RU2490605C1 - Device to measure water level in watercourses of mountain-piedmont area - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: device to measure water level comprises a reservoir 2 installed on the coast of a watercourse 1 with a pressure sensor 3 (differential manometer) connected by means of a discharge tube 4 with an elastic chamber 5, which is fixed to the upper plane of the horizontal diaphragm 6 with holes 7. By means of a pipeline 8 a reservoir 2 is communicated with a well 9. The pipeline 8 is installed with an inclination towards the bottom of the well 9. The well 9 is covered with a double-layer closed chamber 10 of a water resistant soft elastic material with sealed ends and is fixed to the upper edges of the sides of the well 9 by means of clamps. The cavity of the chamber 10 reservoir by means of a tube 11 via a three-way valve 12 is communicated with atmosphere and a source of compressed air 13. Above the well 9 over the double-layer closed chamber 10 there is a protective cover in the form of a grid 14, having a dome-like shape. The grid 14 is fixed with one end to the bottom 15 of the watercourse 1 by means of a hinged joint 16 in the form of a horizontal axis and has a drive 18. The side walls of the well 9 are made with cantilever walls 20 arranged under the lower layer of the double-layer closed chamber 10 by two rows meeting at the bottom of the well 9.

EFFECT: higher accuracy of measurement by exclusion of sedimentation effect at device components.

2 cl, 3 dwg

Description

The invention relates to hydraulic structures, and in particular to devices for measuring levels and flow rates of water in canals and rivers, and can be used in water management.

Water gauging posts are known, including a well arranged on the shore and connected via a pipe to a channel or river, a rail installed in the well, a level recorder installed at a level on a sturdy table or brackets, taking into account the possible amplitude of fluctuations in the water level, a booth for protecting the recorder from external influences (Zheleznyakov G.V. Hydrometry. "Spike", M., 1964, p.22-23).

The disadvantages of the described water-measuring structure is the introduction of the pipe and the well itself with sediment. In addition, with large level differences, from practically minimum to maximum, it is difficult to measure with sufficient measurement accuracy due to the influence of siltation of the device elements that are in constant contact with the medium being measured.

It is also widely known that a water-measuring device, including a well with a water-measuring rod, is connected to a channel or river by means of a slit or pipe (Water-measuring structures on reclamation systems. Typical design decisions 820-1-054-86).

A disadvantage of the known water-measuring structure is its low operational reliability due to siltation of the gap or pipe and the well itself, which reduces the accuracy of the measurement due to the influence of siltation of the device elements that are in constant contact with the medium being measured.

Also known is a water-metering structure for watercourses of a mountain-foothill zone, including a well, a level measuring device, a watercourse, a pipeline, one end of which is connected to the well and a horizontal diaphragm with a hole installed in the well (USSR author's certificate No. 1640288, cl. ЕВВ 13 / 00, 1988).

This type of water-measuring device has a constant flushing flow for sediment discharge and cannot take into account the measurement of the magnitude at minimum fillings of the water level in the watercourse, the flow of which is variable in direction. In addition, the range of measured water levels and flow rates and settings is limited and the measurement accuracy is low due to constant variable discharge of water with sediments affecting the siltation of the elements of the device, i.e. the operation of the elements of the device in constant contact with the measured medium occurs with a restriction on the discharge of water with sediment. All this leads to disagreements between consumers, especially in the mountain foothill zones.

The purpose of the invention is to improve the measurement accuracy by increasing the measurement accuracy by eliminating the influence of siltation of elements of devices that are in constant contact with the medium being measured.

This goal is achieved in that the device for measuring the water level of watercourses of the mountain-foothill zone, including a well, a device for measuring the level, a watercourse, a pipeline, one end of which is connected to the well, a horizontal diaphragm, is characterized in that in order to increase the accuracy of measurement for due to the exclusion of the influence of siltation of the elements of the device in constant contact with the measured medium, it is equipped with a reservoir filled with a working fluid installed below the bottom of the watercourse and connected by a pipeline with a well blocked by a two-layer closed chamber made of soft elastic material, and the two-layer closed chamber is provided with a protective coating on top having a grating made of a domed shape, which at one end is pivotally fixed to the bottom of the watercourse, while on a horizontal diaphragm located in reservoir, an elastic chamber with a pressure sensor is fixed, filled with a working fluid, the density of which is less than the density of water and viscosity is higher than the viscosity of water, and the two-layer closed The closed chamber is in communication with the atmosphere and a source of compressed air through a three-way valve. Moreover, the side walls of the well are made with cantilever walls located under the lower layer of the two-layer closed chamber with two rows converging to the bottom of the well.

This design of the device, when the cavity of the water metering tank is not directly communicated with the source of the watercourse, in which the water level is determined, and at the same time maintains the operability of the device at minimum water levels and equal to zero, which is ensured by installing the bottom of the tank below the bottom of the watercourse filled with clean water eliminates siltation of the well with sediments, provides water purification and protection against clogging from above above a two-layer closed chamber using a lattice device having a dome-shaped shape, which its end is pivotally fixed to the bottom of the watercourse, while the other freely rests on the bottom of the watercourse. In addition, the placement of an elastic chamber with a pressure sensor on a horizontal diaphragm located in the tank eliminates it from kinks and excludes the effect of siltation of elements of the device in constant contact with the medium being measured. A durable two-layer closed chamber with sealed ends made of soft elastic material is protected from damage by large sediments and floating debris, and the periodic removal of fine fractions of sediment particles is removed by injecting air into the closed chamber cavity until the upper layer forms a convex cylindrical surface of the grating, made dome-shaped, providing self-collapse of small sediments through the grate into the watercourse, which are washed off by the flow of water in the watercourse. After cleaning the surface of the elastic upper layer of the material, air and its upper layer are released under the influence of its own weight and the weight of water, it returns to its original position. Thus, the upper part of the layer of a closed chamber of elastic material, increasing in size, abuts against the lattice in contact with it.

Alternatively, to remove fine sediment fractions from the upper layer of a closed two-layer chamber (when air is injected using a compressor or pump), the grate is brought into a vertical position by a rotating drum through a flexible connection and fixed. Moreover, when the upper layer of the chamber takes the form of a convex cylindrical surface, sediment is washed off and collapsed directly into the watercourse, the flow of which carries it downstream. At the end of the cleaning process, air is released from the chamber cavity, the grate is lowered and its upper layer is returned to its original position under the influence of its own weight and the weight of water, and the lower layer, limited by cantilever walls with two rows converging to the bottom of the well, also rises and returns to its original position. These structural differences from the prototype allow us to conclude that the claimed device meets the criteria of the invention of "Novelty."

The authors are not aware of devices for measuring the water level of a similar design, so they believe that the proposed technical solution meets the criterion of "Significant differences".

Figure 1 shows a device for measuring the level before work, a cross section; figure 2 - the same in the work, in the process of cleaning large fractions of sediment, the cross section; figure 3 is the same, in the process of cleaning from small fractions of sediment, the cross section.

The device for measuring the water level comprises a tank 2 located on the bank of the watercourse 1 with a pressure sensor (for example, an industrial design differential pressure gauge) connected via a pressure pipe 4 to an elastic chamber 5, which is attached to the upper plane of the horizontal diaphragm 6 with holes 7. Through the pipe 8, the tank 2 is in communication with well 9. Pipeline 8 is sloped toward the bottom of well 9. Prior to starting water, well 8 is closed with a two-layer closed chamber 10 made of waterproof soft elastic material with a zagreb etizirovannymi ends, which is attached to the upper edges of the sides of the well 9 using clamps (not shown) and through which the tube 11 through the three-way valve 12 communicates with the atmosphere and the source 13 of compressed air (e.g. a compressor or pump). Above the well 9 above the two-layer closed chamber 10, a protective coating is installed in the form of a domed lattice 14 fixed to the bottom of the watercourse 1 by a hinge 16 in the form of a horizontal axis, and the free end has a bent end of the plate 17 with the drive 18 on the drum 19 on the bank of the watercourse 1, serving to hold the grill 14 in an upright position.

The side walls of the well 9 are made with cantilevered walls 20 under the lower layer of the two-layer closed chamber 10 with two rows converging to the bottom of the well and also narrowing to the last to prevent the lower part of the chamber layer from touching so that, in the presence of compressed air pressure in the cavity of the two-layer closed chamber 10 its lower part of the layer upon acquiring the shape of a convex cylindrical surface, there was a limitation of lowering, and the upper part of the layer with small fractions of sediment 21 gradually rises to the lattice 14, to GDSs it takes the form of convex cylindrical surfaces.

A device for measuring the water level works as follows.

When the water level in the stream 1 changes from minimum to maximum, the water pressure in the well 9 changes, blocked by a two-layer closed chamber 10 made of a waterproof soft elastic material with sealed ends, which moves the water in the well 9 through the pipe 8 into the tank 2, changing the shape of the elastic chamber 5, i.e. the walls of which bend, or rather reduce its volume, creates pressure in the tank 2 on the walls of the elastic chamber 5. This pressure is transmitted via the pressure pipe 11 to the pressure sensor 3 (differential pressure gauge). The working fluid of the chamber 5 can be filled with a reference fluid of known specific gravity, i.e. damper fluid (oil, oil, glycerin), whose density is less than the density of water, and viscosity is greater.

To protect the top of the two-layer closed chamber 10 from siltation with large sediments and floating debris, as well as from damage to the upper part of its layer, a lattice 14 made of a domed shape, i.e. provides the sliding of large sediments and floating debris and washing them off from the grate 14 directly along the course of watercourse 1.

To remove fine sediment fractions from the upper part of the chamber 10 layer layer and eliminate the harmful effect of sediment accumulated on it, they are discharged by pumping air using a compressor or pump and emptying the chamber 10 alternately. In this case, the upper layer of the chamber 10 with the contents on it is subjected to internal pressure in small fractions of sediment 21 gradually rises and, when it takes the form of a convex cylindrical surface, adjacent to the arch of the lower part of the lattice 14 of a dome-shaped shape, the nano is pressed owls through the grate, self-collapse and sediment wash-off into watercourse 1, and the lower layer of chamber 10 is limited by cantilever walls 20 by two rows converging to the bottom of the well 9. At the end of cleaning, air is released from the cavity of the chamber 10, and the upper layer, under the influence of its own weight and the weight of water, returns to its original position, the upper and lower layers of the chamber 10 are gradually connected.

Alternatively, to remove fine sediment fractions from the upper layer of a closed two-layer chamber 10 (when air is injected using a compressor or pump), the grill 14 is brought into a vertical position by a rotating drum 19 through a flexible connection 18 and is fixed. In this case, the upper layer of the chamber 10 takes the form of a convex cylindrical surface, sediment is washed off and collapsed directly into the watercourse, the flow of which carries them downstream. At the end of the cleaning process, air is released from the cavity of the chamber 10, the grate 14 is lowered and the upper layer is returned to its original position under the influence of its own weight and the weight of water, and the lower layer also rises and returns to its original position.

Thus, the increased measurement accuracy is automatically supported by eliminating the influence of siltation of the device elements that are in constant contact with the medium to be measured, and the grate ensures the cleaning of water from large sediment and debris and protection from damage to the soft elastic material of the two-layer closed chamber 10. In addition, for inspection and repair of the elements of the well device, the grill 14 is brought into a vertical position by the rotating drum 19 through the flexible coupling 18 and is fixed.

Using the simplest equipment (pump or compressor) for pumping air under a pressure of not more than 0.1 MPa can thereby significantly improve the reliability of the closed two-layer chamber 10.

Thus, the installation of the tank below the bottom of the watercourse, protection from damage to the soft elastic material of the two-layer closed chamber and other elements that are in constant contact with the measured medium, can completely eliminate the disadvantages inherent in known water-measuring devices, and thereby improve the accuracy of measurement.

Claims (2)

1. A device for measuring the water level of watercourses of a mountain-foothill zone, including a well, a device for measuring the level, a watercourse, a pipeline, one end of which is connected to the well, a horizontal diaphragm, characterized in that, in order to improve the accuracy of measurement by eliminating the influence siltation of the elements of the device in constant contact with the measured medium, it is equipped with a reservoir filled with a working fluid installed below the bottom of the watercourse and connected via a pipeline to the well, an open two-layer closed chamber made of soft elastic material, while the two-layer closed chamber is provided with a protective coating on top having a grating made of a domed shape, which is pivotally attached to the bottom of the watercourse with one end, while an elastic chamber is fixed to the horizontal diaphragm located in the tank with a pressure sensor filled with a working fluid whose density is less than the density of water and viscosity is greater than the viscosity of water, and a two-layer closed chamber communicates with the atmosphere compressed air source through a three-way tap. 2. The device according to claim 1, characterized in that the side walls of the well are made with cantilever walls located under the lower layer of the two-layer closed chamber with two rows converging to the bottom of the well.

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