SU1543000A1 - Arrangement for controlling the level of subsoil water - Google Patents

Description

<p> The invention relates to drainage amelioration and can be used to automate the process of regulating the level of groundwater in drainage and humidification systems. The aim of the invention is to improve the accuracy of water regulation - </ p> </ li> </ ul> <p> 2 </ p> <p> whom regime depending on the groundwater level. A device for regulating groundwater contains a well 1, in which the transporting collector 2, storage tank 3 and additional control tank 4 with inlet 5 and outlet 6 closures are located. When the groundwater level drops, the float 14 of the lower level in the tank 4 opens the drain valve 12 of the over-membrane operating chamber 9 of the inlet valve 5. · The shutter 5 opens and the water first enters the tank 3 and then into the pipelines 15 of the collector-drainage network. The output gate 6 cumulative capacity 3 is closed. When the groundwater level rises above the norm, the float 24 of the upper level is triggered, which opens valve 22 after having exhausted from the working chamber 18 of the output gate 6. The shutter 6 opens and the water from the pipelines 15 of the collector-drainage network is discharged. 1 il. </ P> <p> 1543000 A1 </ p> <p> 3 </ p> <p> 1543000 </ p> <p> 4 </ p> <p> The invention relates to drainage amelioration and can be used to automate the process of regulating the level of groundwater in drainage and humidification systems. </ p> <p> The purpose of the invention is to improve the accuracy of regulation of the water regime depending on the groundwater level. </ p> <p> The drawing shows a diagram of the device. </ p> <p> The device includes a well 1, which is connected to the pipeline of the transporting collector 2. In the well 15 1 there is a storage tank 3 </ p> <p>, and additional capacity 4 control with input 5 and output 6 valves. </ p> <p> Capacity 4 communicated by pipeline 20 7 with groundwater. Pipeline 7 is equipped with a filter. </ P> <p> The inlet shutter 5 consists of a flat membrane 8 and a supramembrane working chamber 9. The working chamber 9 is connected with a 25 impulse tube 10 with a water supply pipe 11, at the end of which an inlet shutter 5 is installed, and a drain valve 12 is installed on the drain of the working chamber 9 the input gate 5. The diameter of the membrane 8 significantly exceeds the diameter of the nozzle 1 1, and the cross-sectional area of the discharge nozzle of the working chamber 9 significantly exceeds the cross-sectional area of the impulse tube 10. The drain valve 12 of the input gate 5 by means of a lever system 13 rigidly connected with the float 14 of the lower level, which is located inside the additional tank 4 control. In the well 1 installed pipeline 15 collector-drainage network. This pipeline is connected in the lower part of the tank 4 with the outlet nozzle 16, on which the outlet 45 of the shutter 6 is installed, which includes the membrane 17 and the supramembrane working chamber 18, and the diameter of the membrane 17 significantly exceeds the diameter of the outlet nozzle </ p> <ul style = "list-style: none;"> <li> <p> 16. The working chamber 18 is connected to impulse pipes 19 and 20, respectively, with tanks 3 and 4, and check valves 21 are installed on both tubes to prevent water from flowing from the working chamber 18 to the tanks 3 and 4. The working chamber 18 has a drain pipe on which the drain valve 22 connected by a lever system 23 with </ p> </ li> </ ul> <p> the float 24 of the upper level installed in the tank 4. The float 14 is installed so that its waterline, taking into account the impact of the lever system 13 on it, is below the optimum level of the groundwater level by the value of the accepted dead zone, allowed by the static excess of groundwater level above the optimal mark. Thus, when the groundwater level is in the optimal range, the valve 12 completely blocks the drain from the working chamber 9 of the inlet valve 5, and the valve 22 completely blocks the drain from the working chamber 18 of the output gate 6. </ P> <p> The device works as follows. </ p> <p> When the ground water level deviates from the preset mark downward, the float 14 lowers and moves the valve 12. As a result, there is a drain from the above-membrane working chamber 9 of the shutter 5, thereby reducing the pressure in the working chamber 9, membrane 8 under the action of water pressure opens the outlet section of the water supply nutrient nozzle 11, and the water from the channel enters the chamber 3. The drain from the working chamber 18 of the shutter 6 is closed, and the pressure in the working chamber 18 due to the presence of impulse tubes 19 and 20 is set in accordance with the levels in Odes in tanks 3 and 4, and the pressure value in chamber 18 corresponds to the larger of these levels and due to the presence of check valves 21 there is no water flow from tank 3 to tank 4 and vice versa. This allows you to get an unambiguous relationship between the groundwater level and the water level in the storage tank 4 and the maximum possible pressure in the supermembrane working chamber 18 of the output gate 6. Due to the fact that the pressure acting on the membrane 17 from the working chamber 18 is not lower than the pressure from the side of the storage tank 3, and the area of the membrane 17 exceeds the area of the orifice of the throughflow outlet pipe 16, the membrane 17 completely blocks the outlet pipe 16. Water from the storage tank 3 enters the pipeline 15 </ p> <p> 1543000 <sup> 6 </ sup> </ p> <p> collector-drainage network and then through the drainage into the soil. </ p> <p> Exceeding the level of groundwater leads to the rise of the float 14 of the lower level, overlapping valves $ 12 </ p> <p> the drain from the working chamber 9 and the pressure in it. Thus, the input gate 5 closes, i.e. the membrane 8 overlaps the outlet nozzle, θ ka 11 and stops the flow of water into the nutrient tank 3. </ p> <p> When the groundwater level rises above the maximum permissible elevation, the float 24 of the upper level 15 floats, valve 22 opens the drain from the supermembrane working chamber 18, the pressure in the working chamber 18 drops, the membrane 17 opens the opening of the outlet nozzle 16 and thus The discharge of water from the pipelines 15 of the collector-drainage network. </ p> <p> Lowering the groundwater level to the permissible elevation causes the overflow of the drain from chamber 18 by valve 22, 25 </ p> <p> increasing the pressure of the water in the working chamber 18, blocking the opening of the outlet nozzle 16 by the membrane 17 and stopping the discharge of water from the pipeline 15 of the collector-drainage network. 30 </ p>

Claims (1)

Claim A device for regulating the level of groundwater, including a well with a cumulative tank installed inside it, which in the upper part is connected via an inlet diaphragm valve to a water supplying supply nozzle com, and in the lower part it is connected to a drainage collector, docked to the outlet pipe of the storage tank, ending with an output membrane valve, through which the storage tank is connected to the transporting collector, and the membrane valves have supermembrane working chambers with drain and control tubes, characterized in that In order to improve the accuracy of regulation of the water regime depending on the groundwater level, the inlet and outlet diaphragm closures are designed as flat valves. diaphragm, whose membranous working chambers on the drain pipes have drain valves, and the storage tank is equipped with an additional valve control capacity connected in the lower part to the groundwater, inside of which the floats of the lower and upper levels are mounted, connected via lever systems with the inlet and outlet drain valves respectively shutter, and the working chamber of the input shutter is hydraulically connected by a pulse tube with a water supply feeding pipe and a drain tube - with an additional noy capacity management, and the operation of the output gate chamber is provided with check valves on the impulse lines and fluidly connected with the additional pulse tubes and the storage capacitance and the discharge tube - to a conduit transporting the reservoir.