RU2547406C1 - Drainage system - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: drainage system comprises a collector 1 connected with the drains 2 entering into it, vertical tubes 3 and a device for flushing of sediments. The device for flushing is made of perforated pipes 4 in the form of air outlets 7 arranged inside the drains 2 attached to the upper part of the pipes above the bottom. The perforated pipe 4 by the metal barrel 6, placed in the tube 3 is connected to the pressure hose 8, which inlet is connected to the discharge pipe 9 with the valve 10 of the receiver 11. The receiver 11 is connected to the compressor 12 generating the compressed air. The compressor 12 is connected to the timing relay. The invention increases the transporting capacity of disturbance sediments and other compounds in the drain cavity and accelerates their removal into the open channel 17.

EFFECT: increased efficiency of flushing and increased drainage term by air exposure to sediments.

2 cl, 2 dwg

Description

The invention relates to the field of land reclamation and can be used when washing from sediment in closed drainage systems.

A reclamation system is known, equipped with flushing and evacuating nozzles installed in the nodes of the drain connection with pressure distribution pipelines - directly behind the check valves, while the lower end of each nozzle is communicated by means of a distribution pipe and drain, and the upper one is brought to the surface of the earth and is equipped with a sealed cover ( Patent RU 2022098, class E02B 11/00, 1994).

The disadvantage of this system is that after the end of each irrigation, water is uselessly discharged outside the reclaimed massif, the washing process is slow, since the flow rate from the pipeline is insufficient for intensive erosion of sediment. In addition, the system requires numerous trap pockets along the length of the pipeline for sedimentation of large sediments, which makes it more expensive to build such a system, while this causes large local resistance to water movement along the length of the pipeline and at the end of the water flow velocity can be reduced below the calculated ones, resulting in the transporting ability of drainage from drains decreases sharply. Another disadvantage is that the application area, for example, under pressure from a flexible hose, is limited to a point method in a short pipe section, without affecting the entire length of the pipe to the mouth, where the prism of sediment deposits increases significantly.

A drainage system is also known, including a collector connected to drains flowing into it, and observation wells, pipes with ferromagnetic plugs and flexible threads attached to them located in the cavity of the drains and collectors are installed at the junction of the drains with the collectors and at the sources of the drains, while drains are connected to the collector through nozzles (Patent BY 8089, class E02B 11/00, 2004).

The disadvantages of this system are the low reliability and durability of the flexible thread, since, although they should have sufficient strength in groundwater with an aggressive environment, their frequent pulling requires special skills and manual efforts on both sides, high pulling loads on the threads, abrasion her when working with sediment. In addition, this requires frequent visual observation or the use of additional costs for determining the place of blockage of drains, which also causes a rise in the cost of the system as a whole, especially when there is a large length and quantity of drains and a sufficiently large number of them on the array. At the same time, the service life is also reduced due to increasing tensile stresses in the material of the threads by each hand pulling them in the seals of the deposits due to repeated pulling of the thread. In addition, there is complexity and the complexity of the execution and requires large pressures of water, which leads to disruption of the joints of the drainage pipes.

Another disadvantage is that over time, the drainage capacity can drastically decrease. The reason is the formation of various deposits on the inner surface of the pipes, the formation of which occurs due to the prolonged lack of drainage treatment. All this increases the hydraulic resistance by 2 times or more (operation for long periods) and causes excessive pressure losses.

The objective of the invention is to increase the washing efficiency and increase the drainage time by exposure to air deposits.

This goal is achieved by the fact that the drainage system, including a collector connected to the drains flowing into it, nozzles and a sediment flushing device, the flushing device is made of perforated tubes in the form of air outlets placed inside the drains, fixed to the upper part of the pipes above the bottom, having the initial section of the outlet in the form of a metal barrel, placed in the pipe and connected to a source of compressed air supplied briefly by a compressor, connected to a time relay, etc. and this duct is paired with the receiver via a pressure hose.

In addition, the perforated tubes along the entire length of the drains are made of a smaller diameter relative to the inner diameter of the drains.

This embodiment of the drainage system makes it possible, in comparison with the prototype, to automate the process of protecting drainage pipelines by flushing the cavity from sediment and other impurities deposited on the walls of the pipelines, washing out along the entire length and cross section with a stream of compressed air exiting through the perforated holes of the pipes connected to the compressor through a predetermined time interval. This interval is set according to operating conditions. The destruction of deposits, expressed along the length of the pipes, by the command of the time relay is made by briefly turning on the compressor, which accumulates compressed air in the receiver for air to flow along the entire length of the perforated tube and to enter the drains, where the air mixes with water, causing wave phenomena along the length of the drains, increasing and the speed of movement of suspended particles, and also due to the fact that these deposits are still quite loose, fragile and their adhesion to the walls of the drainage pipes is insignificant. The washing time of sediment and various impurities is reduced. The inner walls of the pipeline are washed and filled with an elastic medium - air, which mixes with water. The air jets exit the holes of the perforated tube with high pressure (speed) and erode both deposits and wash the inner walls of the drain pipes, deposits are removed by significantly increasing the speed of water along the entire length of the drain into the collector, then into the open channel. The ability of compressed air does not allow particles to settle to the bottom and along the length of the pipeline over a large extent. Compressed air is supplied from the compressor from the air duct and further to the perforated tubes fixed to the upper part of the pipe cavity (arch of the drain pipe), i.e. above the bottom, which allows not only to wash the cross section of the inner walls of the pipeline, but also makes it possible to flush from the bottom of sediment, there is an active stirring up, lifting of sediment.

The free space along the pipe cross-section allows floating particles to float freely to a suspended state and, together with a stream saturated with air, they enter the collector and then into the open channel. There is no pulling force of the device for washing sediment, there are no open inspection wells, which allows washing water with dissolved air to exit directly through the collector into an open channel, while the drainage capacity remains set by the initial calculation.

The proposed device allows without large expenses at the same time during the construction of drains on the drainage array to hold the perforated tubes inside the cavity of the drains and fasten them above the bottom of the pipes. Therefore, immediately after construction, it makes it possible in many cases to exclude from the technology of work on the drainage device the laborious and ineffective operation of laying a flexible thread and securing the ends in the nozzles.

In addition, the increased reliability of tubes made of polyethylene and other flexible tubes used in modern technology for their manufacture in industry, allows you to make a wide selection of such flexible length tubes. They can be manufactured in factory workshops on a conveyor belt for broaching in special machines. This, in turn, ensures the mass production of such perforated tubes with ferrules to fasten joints to each other during construction. Service life not less than 50 years. Water losses for flushing are reduced and labor productivity of personnel on the drainage system is increased. Thus, the flushing pulse is supplied not from the device that controls the difference in water levels in the device, but from a time switch that turns on the compressor for flushing the drain with compressed air for a short time, followed by mixing with water.

The possibilities of such a system are not limited, since the device along the length of the perforated tubes fixed above the bottom in the drain cavity does not exert any hydraulic resistance to the flow and does not reduce the flow capacity of the stream saturated with suspensions when the water moves towards the collector, then into the open channel.

The economic efficiency of the proposed drainage system consists in combining in one technological cycle the tasks of optimal water flow for washing the drain and the collector itself under pressure, additionally transporting sediment under pressure of compressed air dissolved in water, since there are no open numerous material-intensive viewing wells along the length of the collector, which interfere with mechanized tillage during agricultural work.

A comparative analysis of the proposed technical solution and the prototype shows that in the claimed combination of features, some of the essential features are new, therefore, the claimed solution differs from the prototype and meets the criterion of "significant differences".

Figure 1 presents a diagram of the drainage system in plan; figure 2 is a section aa in figure 1, a cross section of the drain, collector and pipe.

In all figures, the direction of movement of water and air is shown by arrows.

The drainage system includes a collector-collector 1 connected to drains 2. Vertical nozzles 3 equip all the sources of drains 2 during the construction of the collector-drainage network. At the same time, inside the cavity of the drain 2, the perforated tubes 4 of small cross section are fixed (fixed), which can be made by various manufacturing methods.

The tightness of the holes of the vertical pipes 3 below the plow layer is ensured by a cover 5 in which the metal barrel 6 is installed. The lower end of the metal barrel 6 is rigidly connected to the perforated tube 4, which has air outlets 7 around the perimeter in a checkerboard pattern, and the upper end through a flexible hose 8, the inlet of which is connected to the discharge pipe 9 with a valve 10 with a receiver 11, with a source of compressed air, a compressor (K) 12 connected to a time relay (P) 13 (relay device not showing but). The pressure hose 8 of the composite structure, consisting of individual links of a given length between the drains, is equipped with valves 14, 15. The connections of the hose, metal barrel and tube are made by hermetically separable connecting fittings 16, for example, clamps. At the end of the drain (mouth), a water outlet 17 is made, which serves to supply water to the collector-collector 1. The heads of the metal barrel 6 are closed by a stopper 18 and their heads are not brought to the surface of the earth, since they are damaged or destroyed during mechanized processing soil when loosening and plowing. They open only if it is necessary to flush the drainage with the collector and exit the flow with sediment into the open channel 17.

The number of simultaneously drained drains 2 is determined based on the accumulated volume of compressed air in the receiver 11 associated with the operation of the compressor 12 when the time relay 13 is automatically turned on. Pressure measuring devices are installed on the receiver 11 itself (not shown in the drawing). In addition, the flow rate of compressed air depends on the design of the perforated tube 4, its diameter, working length, size of the air outlet 7, their frequency of placement along the length of the tube 4. Thus, all dimensions are determined by the calculation during the design of the drainage system.

Flushing the drainage system is as follows.

Install the compressor unit 12 with the receiver 11, which has a flexible pressure hose 8 of the required length in its kit and lay it along a series of vertical pipes 3, knowing their location at the source of the drains 2. The beginning of the hose 8 is connected to the pipe 9 with the valve 10 of the receiver 11, and the end or its branch is connected to a metal barrel 6 over the cover 5 of the pipe 3 and hermetically fixed by tightening the connected fittings 16.

After performing these operations, compressed air is supplied from the receiver 11 and using the valves 10, 14, 15 the number of simultaneously running drains for flushing is established, depending on the accumulated air volume in the receiver 11, which can be simultaneously filled with compressor 12 by the command of the time relay 13 in automatic mode work from the signal coming from the devices installed on the receiver 11 (not shown in the drawing for simplicity). At the same time, the discharged air from the holes 7 of the perforated tube 4 exerts a disturbing effect on the water flow in the drain 2, the sediments are actively stirred up and return to their suspended state, then they are carried away by the water flow. As a result of this, transportation of agitated particles is improved, and previously settled iron compounds on the inner surface of the pipe are also washed off with a significant increase in the speed of water movement to the closed collector 1, through which they are further transported to the open channel 17.

After washing the first group of drains, washing the second, third, etc. groups until all drains connected to this collector are flushed. As a result of this effect, intensive mixing and transportation of sediments occurs, and their forward movement along drain 1 is created, which allows self-washing of all drains and connection nodes with an increased water velocity along the entire length of the drain, i.e. from its source to its mouth.

After performing these operations, turn off the receiver 11, the compressor 12 and move to a new position in case of limited length of the pressure hose 8, composed of separate sections along the length.

The system also allows a combined method, i.e. fill, for example, with compressed air the pores of the soil and thereby create aeration in the soil.

The drainage system allows regular flushing of closed drainage several times a year without large expenditures of labor and money on large areas immediately after construction and during long-term operation, which in many cases reduces the number of inspection wells and connecting elements from the work technology, improves the conditions of water flow in drains. It eliminates the laborious work when operating flexible threads for pulling in the collector and in drains with nozzles, which is ineffective in practice, while the cost of washing drains when using the present invention will decrease by at least 2 times. At the same time, it will also make it possible to increase the efficiency of regulating the washing of drains of drained lands after a predetermined time interval by significantly increasing the speed of water movement, the hydraulic mixture is carried out to the collector, then to the open channel.

Claims (2)

1. A drainage system comprising a collector connected to drains flowing into it, nozzles and a washing device from sediment, characterized in that in order to increase the washing efficiency and increase the drainage time by exposure to deposits, the washing device is made of perforated tubes in the form of air outlets holes located inside the drains, fixed to the upper part of the pipes above the bottom, having an initial branch of the branch in the form of a metal barrel, placed in the pipe and connected to the source for compressed air supplied briefly by a compressor connected to a time relay, while the duct is connected to the receiver via a pressure hose. 2. The system according to claim 1, characterized in that the perforated tubes along the entire length of the drains are made of a smaller diameter relative to the inner diameter of the drains.

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