RU2532516C1 - Vacuum drainage system - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to the field of land reclamation and can be used for draining soils in heavy-textured soils, as well as in regulation of the water level in upper pools of bulkhead structures in irrigation and drainage-humidification channels. The system comprises an inlet 1 and an outlet 28 drains, a storage container 2 and a chamber 3 connected by the pipe 4. The chamber 3 is placed in an inspection manhole 5, in which a siphon is mounted. A float 18 is placed in an additional chamber 20 and is provided with a load 19 with a variable mass. The system comprises a three-port articulation linkage, the first port 8 of which is pivotally connected to the first horizontal axis of rotation 7. A shutter 6 is connected to the axis of rotation 7 with the ability of rotation and fixing the shutter in the end positions by means of clamps on the output head of the chamber 3 which is connected to the inlet pipe. The second port is made in the form of a rod 9 mounted on the second horizontal axis of rotation 11 and connected to a lever 10. The lever 10 is pivotally connected to a rod 12 rigidly connected to the float 18. The rod 9 by a lever 13 with a slider 14 is connected to a rack 15, on which a limiter 16 is secured using a retaining screw 17. In the bottom of the additional chamber 20 there is an inlet 23 with the located valve 24 connected to a float sensor 25. The inspection manhole 5 is equipped with a siphon made in the form of a vertically mounted cylindrical nozzle 29 connected to the outlet 28 drain, and a cap 30 located above it. The combination of the articulation linkage with the floating drive mounted on the wall of the chamber (well) with control elements enables to avoid imbalances by moving the shutter 6 on the axis 7, and the operation of the siphon also enables to adjust automatically water discharge to the outlet drain with the stable flow rate.

EFFECT: system is reliable and stable in operation, it has continuous monitoring of the water level and eliminates an emergency.

3 cl, 2 dwg

Description

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

Known regulator of the groundwater level, including a shut-off element with a float actuator and a rod mounted on the head of the drain located in the drainage well, the shut-off element of which is made in the form of a L-shaped nozzle with drainage windows equipped with a removable shutter-glass installed on it with the possibility of free movement and fixation in extreme positions and connected with the float actuator, while the glass is connected by means of removable mounting brackets to the rod of the float drive when changing the position of the L-shaped pipe to the opposite. In addition, for the purpose of a fixed connection, the shutter glass has an internal circular roller with a slot, and the L-shaped pipe in the upper part is equipped with three clamps located at an angle of 120 °, and in the lower part there is a support disk (USSR Author's Certificate No. 1645360, class E02B 11/00, 1991).

However, the regulator has a low level stabilization accuracy, it requires sufficient efforts to control the shutter-glass in the reset mode at the upper position of the locking element and is characterized by the complexity of the design. The device of the shutter windows provides for periodic cleaning of the latter, which complicates the operation of the regulator. At the same time, it does not provide sufficient speed, since part of the energy of the water is spent on overcoming the hydraulic resistance of the outflow of water through the shutter-cup, and also does not allow remote control and monitoring.

Also known is a groundwater level regulator containing a pipe segment, a shut-off element, consisting of a rigid structure with a lever device located on it with a load and a float actuator (USSR Author's Certificate No. 871153, class G05D 9/02, EV 11/00, 1981) .

This device is unreliable due to pipe friction in the pipe, debris and the inability to control the system to completely balance the lever device and is difficult to manufacture. In addition, it does not provide sufficient accuracy and speed of regulation, and also does not allow remote control and monitoring. Moreover, the design of the locking element and the location of its deck lead 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 reliability of its operation, and the lever mechanism on a rigid structure with a load with complex breaks in the connection also increases the forces on the float device, and therefore, reduce the reliability of the device.

Closest to the proposed invention in technical essence is a vacuum drainage system containing discharge and supply drains, a storage tank in communication with a drainage drain through a siphon, a manhole in which a siphon and a storage tank are mounted connected by a pipe, and a float (USSR Author's Certificate No. 1381241 , CL E02B 11/00, 1988).

The disadvantages of the known vacuum drainage system is that it does not provide sufficient accuracy and speed of regulation, and also does not allow remote control and monitoring. The float shutter drains the process of completely opening the drain for a long time 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, while the design of the float shutter and its location it leads to the need to create significant efforts to overcome the hydrostatic pressure acting on the entire area of the float valve when it is opened, difficulties arise due to t rhenium and in the float itself when opening and closing the shutter (warps). These disadvantages reduce the reliability of the device and, consequently, the reliability of its operation.

The purpose of the invention is to increase the efficiency by increasing the speed and accuracy of regulation.

This goal is achieved in that the vacuum drainage system containing the discharge and supply drains, the storage tank communicating with the discharge drain through a siphon, a viewing well, and a float, contains a three-arm pivot-lever mechanism, the first shoulder of which is pivotally connected to the first horizontal axis of rotation, with which the shutter is connected with the possibility of rotation and fixing in extreme positions by means of clamps on the output head of the camera, paired with the supply pipe and which is located in the inspection well, moreover, the restriction mechanism in the form of a slider connected by a lever and connected to the second shoulder in the form of a rod is movably mounted on the riser, and the second limiter is installed below the slide with the lever fixed by the locking screw, and interacts with the latter when the shutter is open, and the second shoulder is pivotally connected with a lever pivotally connected to the rod, rigidly connected to the float installed in the additional chamber and balanced by the weight of the rod below the float, while in the bottom of the additional chamber an inlet with a valve located connected to the float sensor. In addition, the siphon contains a float located under the cap and a valve installed in the hole connecting the cap cavity to the atmosphere and connected to the float on which the end of the flexible tube is connected, connected by a tube to the Venturi nozzle, and the valve in the upper part of the cap is mounted for movement on the stock. In this case, the installed float in the additional chamber is equipped with a load with a changing mass.

The proposed vacuum drainage system is aimed at eliminating these drawbacks due to the design, which allows to reduce the hydrostatic pressure when the shutter is opened due to the design and balance the system of the float part and the specific mass of the cargo, as well as the interconnection of the valve with the float level sensor, and increase the speed of shutter release in a chamber associated with the tip of the supply pipe with a storage tank. In addition, the siphon also has a high capacity for speed, and the air outlet does not introduce constant artificial disturbances in the stabilization of the discharge flow into the discharge drain, and is used only for disturbances in the inspection well, causing an increase in flow to a predetermined value.

Figure 1 shows a vacuum drainage system, a General view; figure 2 is a view of figure 1.

The vacuum drainage system includes a supply drain 1, a storage tank 2, a chamber 3 connected by a pipe 4 located in a manhole 5, and a shutter 6. The shutter 6 is connected to the first horizontal axis of rotation 7 and to a three-arm linkage mechanism consisting of shoulders 8 -10 articulated, representing the three sides of the parallelogram. The first shoulder 8 is pivotally connected to the first horizontal axis of rotation. The second shoulder is made in the form of a rod 9 and is mounted on the second horizontal axis of rotation 11 and is connected to a lever 10 pivotally connected to the rod 12. The rod 9 is connected via a lever 13 with a slider 14 to the strut 15, on which the limiter 16 is fixed, by means of a locking screw 17. A float 18 and a variable weight mass 19 are fixed on the rod 12 on the rod from the lower side of the float 18, the float 18 being placed in an additional chamber 20. The chamber 20 communicates with the pipe 4 by the chamber 21 through the inlets 22 and 23. The inlet 23 is provided valve 24 with a float sensor 25, and the hole 23 is made with protrusions-stops 26 with windows periodically interacting with the float sensor 25. A calibrated hole 27 is made on the side wall of the chamber 20. At the beginning of the drainage drain 28 there is a siphon made in the form of a vertically mounted cylindrical pipe 29 and a cap 30 located above it, the cavity 31 of which is connected through the valve 32 to the stem 33 with the atmosphere, and a Venturi nozzle 34 installed in the inspection well 5, the narrowing of which 35 is connected to the cap cavity a tube 36, and the venturi nozzle exit is connected to a discharge drain 28. Under the cap there is a float 37 connected by a rod 38 to the float, with the end 39 of the tube fixed to the float, part 40 of which is flexible. The float can be placed in the tank 41 (figure 2), mounted on the cap and connected to the cavity 31 with holes 42.

The system operates as follows. The water flowing into the drain 1, flowing down a slope, enters the storage tank 2. The storage tank receives until the water in it fills the chamber 21, the float sensor 25 pops up and, resting upon contact, protruding protrusions 26 in the bottom of the additional chamber 20 , raises the valve 24, opens the inlet 23 and the additional chamber 20 is filled until the buoyant force acts on the float 18, and the rod 12 carries the variable weight cargo 19 upwards - it rises, which moves the shoulders 10-8 and entails the opening of the shutter 6 and the passage of water into the inspection well 5 according to the required flow rate. In this case, the equilibrium is violated, since the lifting force of the float 18 is greater than the weight of the part of the shutter 6 on the axis 7, moving downward, acts through the rod 9 on the lever 8, i.e. drives the shoulders 8-10 of the articulated linkage. The rod 9 is fixed in the slider 14 with the lever 13 on the stand 15 and when lowering the rod 9 together with the lever 13 when the shutter 6 is fully open, it interacts with the stop 16, which is fixed with the locking screw 17 on the stand 15 and is fixed, which leads to increase the filling of the inspection well 5 with water.

With the shutter 6 open, water flows from the inspection well 5 into the discharge drain 28, a vacuum is created in the constriction 35 of the Venturi 34, due to which a vacuum is created in the cavity 31 of the cap 30. From the occurrence of vacuum in this cavity, the water level in the cap 30 increases, reaches the ridge and the water begins to overflow into the vertically mounted cylindrical pipe 29, further increasing the vacuum by trapping and removing air from the cavity 30. As soon as the top surface of the overflow layer reaches the end 39 of the tube 36, air suction stops. Since there is no additional decrease in vacuum, an equilibrium state sets in, and the overflow layer keeps its filling value constant, and the siphon maintains a constant flow rate. From the disturbance in the inspection well, which caused a decrease in the predetermined flow rate, the overflow layer becomes smaller, the end face 39 of the tube 36 loses contact with the surface of the overflow layer and air suction from the cavity 31 begins, and the process of overflow layer growth to a predetermined one is faster, since valve 32 is closed ( depending on the installation of the stem 33 in the desired position). And only in the case of a sharp perturbation of the flow rate in the inspection well 5, which caused an increase in the flow rate from the opening of the shutter 6 in the chamber 3 from the predetermined one, and, consequently, the growth of the overflow layer over a predetermined overflow value, the float 37 floats through the rod 38 to the valve 32, which communicates cavity 31 with the atmosphere. When lowering the overflow layer, the float 37 again closes the valve 32 and the flow rate stabilizes.

When the water level in the chamber 20 drops, the buoyancy force on the float 18 with the counterweight 19 decreases, and they are lowered.

The execution of the valve 24 with a level sensor 25 at the inlet 23 in the bottom of the chamber 20 allows you to make a shutter speed by the time the shutter opens in the chamber 3 and pass the excess water into the inspection well 5 until it is completely emptied.

When the level in the chamber 21 decreases, the level sensor lowers and the hole 23 is again closed by the valve 24 under the weight of the level sensor, and the camera 20 is gradually emptied through a calibrated hole 27 located in the side wall of the chamber 20. Moreover, the possibility of emptying the chamber 21 and the chamber 20 is interconnected with the total the area of holes 21 and 27. Excess water from the chamber 20 is discharged through the calibrated hole 27 to the well 5. As a result, the articulated lever mechanism acts on the shoulder 8 and the shutter 6 on the hinge 7 closes the chamber 3. The weight position Shop 18 can be controlled by the load 19 with variable mass. In order to reduce the effort on the float device in the chamber 20, the system is designed so that the total force from the weight of the rod 12 and the left part of the rod 9 with levers 13, 8 and the shutter 6 is balanced with an adjustable weight 19 with a variable mass with a float 18, i.e. . the product of the weight of the elements by the distance of effort is taken into account (not shown in the drawing for simplicity).

The system allows for regulation on drains with an increased slope of the terrain in automatic mode, to increase the accuracy of regulation of water flow in the inspection well and increase the speed of the regulatory body. The vacuum drainage system is reliable and stable in operation, the water level in the well quickly stabilizes to the required costs; automatic continuous level control eliminates an emergency.

The proposed system has the listed advantages because automatic control is more reliable than the known one. After emptying the container 2, the vacuum drainage system is ready for a new cycle of operation.

Claims (3)

1. A vacuum drainage system containing drain and feed drains, a storage tank communicating with a drain drain through a siphon, a manhole in which a siphon is mounted, and a storage tank connected by a pipe, and a float, characterized in that in order to increase work efficiency by To increase the speed and accuracy of regulation, it contains a three-arm pivot-lever mechanism, the first shoulder of which is pivotally connected to the first horizontal axis of rotation, to which the shutter is rotatably connected fixation in extreme positions by means of clamps on the output head of the camera, paired with the supply pipe and placed in the inspection well, the restriction mechanism in the form of a slider connected by a lever and connected to the second shoulder in the form of a rod, is movably mounted on the riser, and the second limiter is installed below the slider with a lever secured by a locking screw and interacts with the latter when the shutter is open, and the second shoulder is pivotally connected to a lever pivotally connected to a rod rigidly connected to the float m, installed in the additional chamber and load balanced by a lower float rod, wherein in the bottom of the additional chamber with an inlet placed a valve connected to a float sensor. 2. The vacuum drainage system according to claim 1, characterized in that the siphon contains a float located under the cap and a valve installed in the hole connecting the cap cavity to the atmosphere and connected to the float on which the end of the flexible tube is connected, connected by a tube to the Venturi nozzle moreover, the valve in the upper part of the cap is mounted for movement along the stem. 3. The vacuum drainage system according to claim 1, characterized in that the installed float in the additional chamber is equipped with a load with a variable mass.

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