RU38529U1 - DROP IRRIGATING DEVICE - Google Patents

Abstract

ESSAY

The utility model relates to agricultural machinery, namely, to devices for drip irrigation of crops using drip irrigation methods and can be used to fertilize or moisten various crops when grown in open ground, greenhouses, orchards and vineyards, especially in arid areas where the amount of water suitable for watering plants is limited.

The utility model is based on the task of creating a drip irrigation device with reduced siltation and the possibility of washing them.

The improvement relates to a drip element installed in the piping of a drip irrigation device. The drip element contains an inlet means, with a channel associated with the through-cavity of the element, an outlet means made on the outer side surface of the element at the location of the outlet of the pipeline, and a channel for reducing pressure, made on the outer side surface of the element connecting the inlet means of the element with graduation tool. According to a utility model, said pressure reducing channel is located along the elongated side of the drip element and has alternating projections and depressions on opposite surfaces of the channel sides so that protrusions of one side are located against depressions of the opposite side. The inlet means is made in the form of an annular groove forming a cavity in which the said channel is connected, connected with the through internal cavity of the element, and a filter is installed at its entrance. The filter mainly consists of interconnected alternating sections with a vertical and horizontal arrangement of filter threads.

Description

The utility model relates to agricultural machinery, namely, to devices for drip irrigation of crops using drip irrigation methods. The utility model can be used to nutrition or moisturize various crops when they are grown in open ground, greenhouses, orchards and vineyards. The utility model is especially effective in arid areas with a limited amount of water suitable for watering plants.

Drip irrigation is the most promising way to maintain the required soil moisture needed to moisten and nourish plants. It consists in supplying small doses of water or a nutrient solution to the plant roots. It should be said that the words “water” and “pipeline” used in presenting the essence of the claimed utility model should be understood more broadly, namely: a pipeline is a means for supplying fluid from a source to an irrigated plant, whether it be a flexible hose or a rigid pipe of any known profile; water - any fluid, mainly a liquid nutrient solution for feeding or moistening plants.

Various systems and devices for drip irrigation are known and used. The most common irrigation systems consist of pipelines with sequentially installed flow turbulators - emitters. Emitters significantly reduce the flow head and thereby form droplets. (For example, EPO patent No. 0309162, IPC ⁴ AO 1025/02, 1989; application WO 98/02251, IPC ⁶ B05B 15/00; application WO 98/50167, IPC ⁶ B 05815/00). These droplet-forming systems cause a decrease in droplet formation along the length of the pipeline due to the sequential

installation of emitters and large losses of pressure on the flow turbulence. In addition, the systems are subject to frequent clogging, and clogging of the pipeline in one place leads to inoperability of the entire subsequent section.

Devices are also known in which drop-forming elements are installed along the outer wall of the pipeline. The droplet-forming element of the device consists of an inlet connected to an opening in the wall of the pipeline and an outlet connected to each other by a labyrinth channel extending along the entire length of the pipeline. (For example, US patent No. 3870236 NKI 239-542, MKI B 05 V 15/00, 1975; No. 3873030 NKI 239-542, MKI B 05 V 1/30, 1975; No. 3896999, NKI 239-107, MKI B 05 In 1/32, 1975). These devices have the same disadvantages as described above, since they retain the same scheme of sequential transmission of the entire stream through all the labyrinth channels.

Closest to the claimed utility model is a drip irrigation device described in US patent No. 4728042, NKI 239-542, IPC ⁴ 05 05 15/00, 1988. The drip irrigation device consists of a pipe in which through outlets are formed, and elongated drip elements installed inside the pipeline along its length at a distance from each other. Attached to one end of the pipeline is a means for connecting to a source of pressurized water. Drop elements have a through internal cavity for passing water through it through a pipeline. On the outer surface of the element made a set of channels to reduce pressure. The specified set is a set of slotted annular grooves connected in series with each other by secondary channels and forming a labyrinth. The drip element also contains inlet and outlet means. The inlet means is a through channel connecting the internal cavity of the pipeline with the beginning of the first channel of the maze. The outlet means is a cavity on the outer side surface of the element,

located at the place of execution of the outlet of the pipeline and connected to the end of the last of these channels. Thus, the inlet means of the element is connected to the outlet means through a labyrinth in which the water pressure is lost and due to this, its output through the outlet means is reduced.

In the described device, a part of the main stream of water passes through the droplet-forming elements, which in the form of droplets leaves through the outlet of the pipeline. This makes it possible to somewhat reduce the disadvantages inherent in the above devices. However, to exclude the possibility of rapid siltation of the channels or to clean the channels does not allow the location and shape of the channels to reduce pressure. The channels have a curved surface, a small length and frequent connections with perpendicularly directed secondary channels. It is practically impossible to wash out settled sediment particles from these channels.

The utility model is based on the task of creating a drip irrigation device, in which by means of structural changes in the shape of the channels to reduce pressure and their location on the drip element, siltation of the channels is achieved, the possibility of their washing, and thus increase the service life of the drip elements and the whole device.

The problem is solved as follows. The drip irrigation device comprises a pipeline including at least one outlet, means for connecting to a pressurized water source and at least one elongated drip element with a through internal cavity mounted inside the pipeline for passing water through it. The specified droplet element contains an inlet means containing at least one channel associated with the through-cavity of the element, at least one outlet means made on the outer side surface of the element at the location of at least one outlet of the pipeline, and at least one channel for

pressure reducing, performed on the outer side surface of the element connecting the inlet means of the element with the outlet means. According to a utility model, said pressure reducing channel is located along the elongated side of the drip element and has alternating protrusions and depressions on opposite surfaces of the channel sides so that protrusions of one side are opposed to depressions of the opposite side. The inlet means is made in the form of at least part of an annular groove forming a cavity in which said at least one channel is made, connected with the through internal cavity of the element, and a filter is installed at its input. The purpose of the groove is to direct water into the channel to reduce pressure.

By positioning the channel along the long side of the element, it reaches its rectilinear directivity and greater length without excessive bending. The protrusions and depressions sufficiently turbulize the flow of water, but they are easily washed and do not create conditions for the sedimentation of silt particles. If necessary, such a channel can be easily washed with high water pressure. The inlet filter eliminates the ingress of large particles into the channels that can clog the channel passage.

Advantageous is the implementation of a drip device, in the annular groove of which an additional channel is formed connecting the cavity of the groove with the cavity of the element located diametrically opposite to the specified channel associated with the through internal cavity of the element, while the additional channel is equipped with a filter.

The filter mainly consists of interconnected alternating sections with a vertical and horizontal arrangement of filter threads.

It is also advantageous to implement a device in which the droplet element contains at least two interconnected channels for reducing pressure, forming two groups located diametrically on the element

the opposite. This contributes to an even greater reduction in water pressure and its more economical expenditure. On the lateral surface of the droplet element, stiffeners located between groups of channels can be made. The arrangement of the channels balances the forces acting on the element. In combination with stiffeners, this reduces the wall thickness of the element.

If the droplet element at the ends contains two outlet means in the form of annular cavities, then the stiffeners located near the outlet of the last channel to reduce pressure have a passage connecting these outlet means and form an additional section for reducing pressure.

In the figures of the drawings presents the predominant embodiment of a drip irrigation device. In FIG. 1 shows a General view of the device with a gap at the location of the drip element; in FIG. 2 is a rear view of a drip element. The presented image of the device along with the description of an example of a specific embodiment of the device in no way limit the scope of claims expressed by the formula of the utility model and confirmed by the description.

The drip irrigation device contains a flexible plastic pipe 1 , which is resistant to the negative effects of temperature, ultraviolet radiation and the influence of agrochemical preparations. At one end of the pipeline, means are provided for connecting to a source of water under pressure (not shown in FIG.). The second end of the pipeline can be connected, for example, with a tank (not shown in FIG.). Drip elements 2 are installed in the pipeline, the number of which can be any, depending on the length of the pipeline. The distance between the drip elements can also be any, mainly from 15cm to 250cm. The indicated features are insignificant and do not affect the essence of the utility model. Drop elements 2 are made in the form of elongated tubular bushings with a through internal cavity 3. Drop elements are installed inside the pipeline 1 s

the possibility of an unhindered flow of water along it. Each element has a sealing protrusion 4 on the peripheral part of each end 4. A second pair of open protrusions 5 located on the outer side surface of the droplet element closer to its middle forms cavities 6 at the ends of the element forming exhaust means. At the location of the outlet cavities 6, the outlet openings 7 are made in the pipeline. There can be one or two openings against each cavity 6. Near the cavity 6, an annular groove is made on one side of the element 8 , forming an inlet cavity, in the bottom of which a hole is made connected with the through inner cavity 3 of the element 2. The hole has a relatively large bore, and the inlet of the hole is blocked by a filter 9. Two holes can be made in the element. In this case, they are mainly located diametrically opposite to each other. Two holes further increase the surface of the inlet. However, the installation of lattice filters on them reduces the area of the passage section, and thus somewhat limits the amount of water entering the annular groove 8. The filter 9 consists of interconnected alternating sections with a vertical and horizontal arrangement of filter threads. On the side surface of the element, labyrinth channels 10 are made to reduce the amount of water pressure that has fallen on the side surface of the element. The channels 10 are located along the elongated side of the element in several rows. In an example of a specific embodiment, the channels are combined into two series-connected and connected groups located diametrically opposite. The channels 10 are interconnected by intermediate channels 11. The channels 10 have protrusions 12 alternating with depressions 13 on opposite surfaces of the sides and are configured so that the protrusions of one side are located opposite the depressions of the opposite side. On the side surface, the element contains stiffeners 14 and 15 located between these groups of channels

10. In this case, stiffeners! 5, located near the exit 16 of the labyrinth channel form a passage 17 connecting the cavity 6, and thus form an additional section of pressure reduction. In addition, stiffeners tighten the design of the element and allow its walls to be made thinner. The predominant wall thickness of the element in the inventive device is 0.6 - 1.1 mm

Drop formation in a drop element occurs as follows. When water is supplied through pipeline 1, it penetrates through the holes in the annular groove 8. Through the annular groove, water enters the labyrinth channels 10. The arrangement of the channels 10 in the form of two groups on opposite sides of the lateral outer surface makes it possible to reduce the resulting force from the pressure forces acting on the element and thereby make thinner the wall of the element. The filter 9 in front of the inlet delays the inclusions contained in the water and reduces the flow of water entering the channels 10. The difference in the orientation of the threads in different parts of the filter prevents the filter from completely clogging. The flow of water, flowing along the protrusions of the labyrinth channels, is turbulized. resulting in pressure loss. Water flows out of the labyrinth dropwise into the annular groove b and then along the lateral surface between the stiffening ribs 15 into the opposite groove 6. From the grooves 6, water in the form of droplets through the outlet openings 7 in the pipeline 1 enters the soil.

The optimum working pressure for which the drop elements of the described construction are designed is 0.8-2.0 bar.

Claims (6)

1. A drip irrigation device comprising a pipeline containing at least one outlet, means for connecting to a source of pressurized water, and at least one elongated drip element installed inside the pipeline with a through internal cavity for passing water, having an inlet means containing at least one channel associated with the through inner cavity of the element, at least one outlet means made on the outer side surface of the element in the place of distribution the position of at least one outlet of the pipeline, at least one channel for reducing pressure, made on the outer side surface of the element connecting the inlet means of the element with the outlet means, characterized in that said channel for reducing pressure is located along the elongated side of the drip element and has on opposite surfaces of the sides of the channel alternating protrusions and depressions, such that the protrusions of one side are located against the depressions of the opposite side , the inlet means is made in the form of at least a part of the annular groove forming a cavity connected to the inlet of the channel to reduce pressure, in which said at least one channel is made, connected with the through internal cavity of the element, while at the input of the specified channel filter is installed. 2. The drip irrigation device according to claim 1, characterized in that in said annular groove an additional channel is formed connecting the cavity of the groove with the cavity of the element located diametrically opposite to the specified channel associated with the through internal cavity of the element, while the additional channel is equipped with a filter. 3. The drip irrigation device according to claim 1 or 2, characterized in that the filter consists of interconnected alternating sections with vertical and horizontal arrangement of filter threads. 4. A drip irrigation device according to any one of claims 1 to 3, characterized in that the drip element contains at least two interconnected channels for reducing pressure, forming two groups located on the element diametrically opposite. 5. The drip irrigation device according to claim 4, characterized in that the drip element on its lateral surface contains stiffeners located between these groups of channels. 6. A drip irrigation device according to claim 5, characterized in that the drip element contains two outlet means made at the ends of the element in the form of annular cavities, while the stiffeners located near the outlet of the channel to reduce pressure have a passage connecting these outlet means .