RU2530529C1 - Vacuum drainage system - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: system comprises a feeding drain line 1, a collecting container 2 connected to an inspection pit 3 by the pipe 4, and a vertical overflow wall 5 with an opening 6. The vertical overflow wall 5 is fastened to the bottom 7 and rigidly embedded in the side walls of the pit 3. The overflow wall 5 is provided with a horizontal shelf 8 directed towards the pipe 4. The inspection pit 3 is communicated with a chamber 9 which has a broken inner wall 10 with an opening for the inlet pipe 12. The lower central part of the broken wall 10 between the chamber 9 and the pit 3 is made as an opening 13 and comprises a seat with a valve 14 on the hinge 15 and the float drive. The chamber 9 is hydraulically connected by the siphon 22 and the vertical pipe 23 to the outlet drain line 24. The siphon 22 is separated from the float drive by the cantilever partition 20 and has a charging tube 25. The relationship in the operation of the inspection pit, the chamber with the float drive, the siphon and other construction elements enables to increase the reliability and accuracy in the work of the construction.

EFFECT: efficient periodic washing from suspended sediments of the construction and the drain line to the source of the collector.

3 cl, 1 dwg

Description

The invention relates to the field of land reclamation and can be used to drain soils that are heavy in mechanical composition, as well as when regulating the water level in the upper pools of the blocking structures on irrigation and drainage channels.

There is a known groundwater level regulator mounted on the head of the pipe, including a body with water outlets and a shut-off element with a float actuator, a shut-off element connected to the float by pivotally connected to them and fixed on the body of the L-shaped lever equipped with a removable load, this locking element is made in the form of a cylindrical glass with a ring-shaped bottom (USSR Author's Certificate No. 871153, class G05D 9/02, E02B 11/00, 1981).

However, the controller is unreliable in operation due to friction of the pipe in the pipe, the inability to control the system to completely balance the lever device, the complexity of the design. The design of the locking element and its placement in the well leads to the need to create significant efforts to overcome the hydrostatic pressure acting on the entire area of the shutter when it is opened. These efforts reduce the reliability of the device and, consequently, the operation, and the lever mechanism system on a rigid structure with a load with complex breaks in the connection also increases the effort on the float device.

Closest to the proposed technical essence is a vacuum drainage system containing outlet and inlet drains, a storage tank in communication with the drainage drain through a siphon, the system is equipped with a viewing well in which the siphon is mounted, and the storage tank is connected to the well by a connecting pipe with a float valve, placed in the well, and an overflow pipe with a check valve, while the siphon is connected to the float valve, a flexible hose, has holes and the float located inside yvayuschy holes (USSR Author's Certificate №1381241, cl. E02B 11/00, 1988).

A disadvantage of the known vacuum drainage system is that it does not provide sufficient accuracy and speed of regulation and does not allow monitoring. The process of operation of the float actuator is delayed to completely open the drain and does not allow to increase the speed, since the shutter, following the float when the level in the inspection well changes, slowly opens and closes the drain hole through which it communicates with the well. Moreover, the location of the design of the float actuator and its location leads to the need to create significant efforts to overcome the hydrostatic pressure acting on the entire area of the float shutter when it is opened, difficulties arise due to friction on the riser (distortions) and in the float itself when opening and closing the shutter . These disadvantages reduce the reliability of operation of the device, and consequently, the reliability of operation, and the complexity of the design.

The purpose of the invention is to increase the reliability and accuracy in the work by maintaining a given difference between the water levels of the well and siphon.

This goal is achieved by the fact that in the vacuum drainage system containing the discharge and supply drains, the storage tank and the inspection well, connected by a pipe, a siphon and a float actuator with a shutter, a chamber with a broken inner wall is introduced, in which a float actuator with a valve is placed, and a hole for the inlet tube is made on the wall, and the siphon has a charging tube, while a vertical overflow wall with a horizontal plate is installed in the well at the bottom, which is directed towards the flow from the connecting side tive tube.

In addition, on the siphon side, the cantilever partition is made with a height coinciding with the mark of the siphon hood.

In this case, the float actuator with the valve is separated from the inspection well in the form of labyrinth partitions.

The proposed vacuum drainage system is aimed at eliminating these drawbacks due to the design, which allows to reduce the hydrostatic pressure when the shut-off valve is opened, to balance the float system and the specific mass of the cargo, and the interconnection of the valve with the float level sensor allows you to maintain a given differential between the water level of the well and siphon . The work of the siphon itself has a great ability to speed up, caused by the opening of the inlet during the initial filling of the chamber and the subsequent automatic maintenance of a given level before the siphon. Isolation of the chamber itself with a float actuator and a siphon from the inspection well with labyrinth partitions and a wall, installation of a horizontal shelf, a culvert and a tube through the walls in the middle part, automatically maintains a predetermined level of a soothing stream of water to divide it into sections. The process of accumulation and emptying of the discharge chamber will continue until the siphon removes all the water, causing water to suck from the inspection well, respectively, the flow of water from the storage tank, while the intervals between discharges are controlled by changing the capacity of the siphon with the charging tube. In addition, the siphon allows you to clean the chamber of sediment, which ensures reliable operation of the valve with a float actuator.

It should also be noted that the presence of a horizontal shelf on a vertical wall fixed to the bottom of the well and the water leaving the connecting pipe from the storage tank with a large slope, turns part of the stream jet back to it, as a result of which there is a helical rotation of the water, additional damping of energy and a further increase in uniformity water surface behind the spillway in front of the valve, i.e. the bottom and surface character of the water movement in front of the opening blocked by the valve, which fills the chamber in front of the siphon, improves.

The system has a simpler design than the known ones, which increases productivity and operation.

Such use of the vacuum drainage system, according to the author, was not known and meets the criterion of "significant differences".

The drawing shows a schematic diagram of a vacuum drainage system in transition mode, General view.

The vacuum drainage system includes a supply drain 1, a storage tank 2 connected to a viewing well 3, a connecting pipe 4, a vertical overflow wall 5 with an opening 6, and a wall 5 is fixed to the bottom 7 and rigidly sealed in the side walls of the well 3. The overflow wall 5 is made with a horizontal shelf 8 in the upper part and directed towards the flow coming from the pipe 4.

The chamber 9 contains a broken inner wall 10, in the rounded wall 11 of which a hole is made for the inlet tube 12. The lower central part of the broken wall 10 between the chamber 9 and the inspection well 3 is made by a hole 13 and includes a seat with a valve 14 on the hinge 15 and a small float 16, fixed to the valve 14. An opening lever 17 is attached to the valve 14, to which, in turn, a large float 18 is mounted, suspended on a holding flexible rod 19. The large float 18 from lateral displacement in the region of the outlet stream from the opening 13 is provided with nsolnoy wall 20 whose lower end is formed at the level of bonnet 21 of the siphon 22, the chamber 9 is hydraulically coupled by a vertical siphon pipe 22 and outlet 23 with drains 24 at a controlled throughput. The siphon 22 contains a charger made in the form of a tube 25, the lower end of which is located in the vertical pipe 23 (drain elbow). In addition, a large float 18 from the intake part of the water by the siphon 22 is simultaneously limited by the cantilever wall 20. Thus, the float actuator with the valve is separated from the inspection well 3 in the form of labyrinth walls.

The vacuum drainage system operates as follows.

The water flowing into the drain 1, flowing down the slope, enters the storage tank 2 connected to the inspection well 3, the connecting pipe 4. Under pressure, the water jet entering the first part of the well 3, hitting the overflow wall 8, forms a helical rotation of the water with air cord. The upper end of the overflow wall 5 forms a threshold with a horizontal shelf 8, rotates part of the jet towards the outlet of the pipe 4, and the other part of the water flow overflows through the horizontal shelf 8 into the second part of the well 3. At the same time, air flows through the hole 6 in the wall 5 water from the first part of the well 3, and the helical flow is somewhat compressed in the vertical section, which reduces the rise of water in it - partially the kinetic energy of the water flow is quenched. Finally, the surface of the water calms down in the second part of the inspection well 3 in front of the hole 13, blocked by the valve 14, and part of the water enters the chamber 9.

With the increase of the set level in the well 3 and the filling of water in the chamber 9 to the level of the location of the small float 16, the valve begins to open and partially greater water consumption. The water level in the chamber 9 rises and rises to the level when the lifting force of the large 18 and small 16 floats becomes equal to and greater than the water pressure on the valve 14, the latter rises sharply and lets water into the chamber 9. Since the volume of the chamber 9 is increased from the intake from the viewing well 3 until the siphon 22 is turned on, and due to the rapid suction of air from the hood 21 through the tube 25 into the drain 24, the siphon 22 is charged at a given hydraulic difference between the upper water level in the chamber 9 and the lower pool connected to Rena 24.

As a result of this, there will be a quick discharge of water through a siphon 22 into drain 24 along with suspended sediment, i.e. the chamber 9 is simultaneously freed from suspended sediment, which ensures the operability of the valve 14 with floats 16 and 18. The accumulation and subsequent discharge of water will occur sequentially, starting from the well 3 to the chamber 9 with a siphon 22 connected to the drain 24, and the volume of water , discharged each time from the chamber 9, it is possible to ensure a high-quality washing of the chamber 9, while the effect of water leakage and through the tube 12 from the second part of the well 3 with the capture of also weighed sediments partially affects. The water discharged into the drains 24 with suspended sediment under pressure flushes the drains along the length, the speeds of which will fluctuate sharply in time. When the water level in the chamber 9 decreases, a large float 18 and then a small float 16 are lowered with it, the weight of the valve 14 increases; valve 14 is closed and ready for the next cycle of operation. Moreover, the hydraulic mode in the chamber 9 during operation of the siphon 22 is characterized by a smooth gradually fading due to the restriction of the cantilever partition 20. The separation of the part of the chamber 9 by the baffle 20 increases the accuracy of regulation by the large float 18 to the valve 14 with the small float 16 and increases the reliability from the rest of the chamber 9 and the well 3 as a result of the implementation of the labyrinth partitions.

Thus, the process of accumulation of capacity 2, well 3, located up to the chamber 9 and their emptying due to the flow of water through the hole 13 into the chamber 9 and its filling will be until the siphon 22 turns on and takes all the water from the chamber 9, moreover the intervals between discharges are controlled by changing the throughput of the hole 13, blocked by the valve 14. In addition, this allows you to clean the suspended sediment of the entire closed drain to its source collector (not shown). Due to the mutual hydraulic connection of the well, the chamber with a float actuator, a siphon and other elements, the reliability and accuracy of the structure increases, and there is an effective periodic washing from suspended sediments of the structure and drain to the source of the collector.

Claims (3)

1. A vacuum drainage system containing drain and inlet drains, a storage tank and a manhole connected by a pipe, a siphon and a float actuator with a shutter, characterized in that in order to increase the reliability and accuracy in operation by maintaining a given difference between the water levels of the well and siphon a chamber with a broken inner wall is introduced, in which a float actuator with a valve is placed, and a hole for the inlet tube is made in the wall, and the siphon has a charging tube, while in the well is installed at the bottom Tikal overflow wall with a horizontal shelf, which is directed towards the flow from the side of the connecting pipe. 2. The system according to claim 1, characterized in that on the siphon side a cantilever partition is made with a height coinciding with the mark of the hood of the siphon. 3. The system according to claim 1, characterized in that the float actuator with the valve is separated from the inspection well in the form of labyrinth walls.