RU2616380C1 - Draining and humidifying polder system - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: draining and humidifying polder system includes the drains, the collector, the main channel with the pump station. The accumulating reservoir is made in the form of the channel 6 with the flooded dam 7. The dam 7 in its upper part is additionally provided with ridges on one level with the flood-free dam 5. Between the ridges of the dam 7 and below the ridges, the outlets of rectangular cross-section with the threshold 11 are made. The outlets are equipped with the rotary retaining wall 12 mounted with an inclination towards the inlet of flood waters and watertightly conjugated via the threshold 11 on the dam 7 between the ridges and below them with the curved stop 13. The rotary retaining wall 12 rests on the props 15 and 16, the mark of its ridge 17 is located below the ridge of the dam 7. On the prop 15, on the floodwater side, the link 18 is fixed, for example in the form of a rope, which is connected with the mark of the ridge 17 of the retaining wall 12. The link 18 is constantly unwound or wound on the drum 19, depending on the operation mode of the rotary retaining wall 12 itself. The overall outlets front is determined according to the conditions of allocation of the estimated flood flow rate to the flooded areas of the dam with 7 ridges with the acceptable overflow rate.

EFFECT: system allows to provide sufficient protection against the flooded dam erosion on the side of flood waters, with minimal damage to the hydraulic structures and the environment while reducing the hydraulic structures erection costs, limiting them only by the costs of the outlets construction along the perimeter of the flooded dam.

6 dwg

Description

The invention relates to a comprehensive land reclamation of agrolandscape and can be applied to the creation of regulation of water regime of soils based on resource-saving technologies.

The proposed technical solution is intended, first of all, for carrying out drainage measures of wet areas, including wetting after a decline in levels in the floodplain of the river. It is used to create new and reconstruct exploited technologies. Its most rational application is the drainage of lands according to the so-called landscape reclamation technology.

A known method of draining the polders, including sequential discharge of water from the polder’s area by gravity and mechanical pumping, the polder’s area is divided into sections and water discharge from them by mechanical pumping is carried out alternately with the simultaneous bypass of water from the plot to the gravity drainage (Copyright certificate SU No. 487980, ЕВВ 11 / 00 from 10/15/1975).

Excessive moisture from surface and groundwater is constantly discharged by the pumping station beyond the limits of drained polders, even after a drop in water levels in the floodplain of the river. In this there is a deficit of soil moisture to moisten it, especially in the summer months of the year. With this design, the drainage of the polders cannot be maintained in the filling channels with water even in the presence of flood waters, i.e. it is limited in application, as it is intended only for drainage of polders.

There is a method of anti-erosion protection of the relief on the polders for growing herbs, including the discharge of water from the polder area, which is divided into sections, and discharge from them is carried out by conducting channels, the polder area is divided into strip tapes 50 ... 60 m wide from each other parallel to the river along the longitudinal the scheme by which the runoff of surface water is delayed, in addition, the runoff of excess surface water and filtering from the soil are discharged by open waste collectors located along it is a river, at the same time, carrying out the discharge of groundwater from strip tapes through gentle slopes of the collectors with the simultaneous self-cleaning of their strip tapes, shrub plantings are planted along their banks on the upper edge of the collector 1.0 m wide, and the discharge collectors are connected to a collective open discharge channel, at the end of which reinforcing structures are arranged, while the collective discharge channel is arranged with a downward slope towards the river and away from the drainage water collection points in a place where it is not affected e by flooding the collector (Patent RU №2563146, E02V 11/00, 13/16 A01V from 28/07/2014).

The method allows you to absorb part of the water flow into the thickness of the groundwater, and the other part of the water flows slowly into the open waste collectors by streams through the near-collector shrub strip in the strip tape of the flooded area, while it also accumulates on the water-holding strip area with shrubby vegetation of collectors located along the banks resulting in reduced nutrient loss. Excessive moisture from the surface and groundwater drains unhindered into the collectors with its further discharge.

Known technical solution is limited in application, because it is intended only to reduce nutrient loss, but not by an intensive drainage and moisturizing process of soil drying after a drop in water levels in the floodplain and the onset of moisture deficiency in the soil of water, in particular in the dry summer season, i.e. with a sharp increased positive air temperature (especially in dry years).

The closest technical solution is a drainage and humidification polder system, including a bunding dam, an accumulating tank, a collector-drainage network, a pump station and a water intake and equipped with an additional bunding dam laid parallel to the main one, and a storage tank made in the form of a channel laid between dams and connected to the drainage network collector (Copyright certificate SU No. 1612050, ЕВВ 11/00 dated 12/07/1990).

The disadvantage of this system is its insufficiently effective operation due to the likelihood of erosion of the flooded dam towards the unsinkable dam (formation of gaps) due to the low strength of the soil, with alternating decreases or increases in levels, i.e. first, the water level rises, then the water level drops from the side of the flooded dam, and this in turn leads to erosion of the dam crest; decrease in operational reliability of work for controlling levels in the soil on the collector, at the mouth of which a downstream water outlet is installed, while a downstream water outlet is installed in the channel.

The technical problem solved by the invention is to provide reliable protection of hydraulic structures in increasing the erosion reduction of the ridge of the flooded dam and the environment while simplifying and cheapening the construction of the entire complex of hydraulic structures, which is especially important when building a polder system, where the restoration of the damaged part of the flooded dam requires more time and money than the installation of special outlets in the direction of the water intake with accumulating mkostyu.

This object is achieved by the fact that the drainage and humidification polder system, which includes an unsinkable bunding dam, an accumulating tank, a collector-drainage network, a pumping station and a water intake and equipped with an additional flooded bunding dam, laid parallel to the main accumulating tank, made flooded in the form of a channel laid between dams and the drainage network connected to the collector, characterized in that the ridge of the flooded dam is made additionally one mark high ke with the crest of the main unsinkable dam and made in the form of a set below the crest of the outlets of rectangular cross section, the common front of the outlets is determined from the distribution of the estimated flow rate in front of the ridge with separate sections of the flooded dike, while the outlets of the rectangular cross section are provided with a rotary retaining wall installed with tilting away from the storage tank from the outside of the exhaust through separate sections of the flooded dam located between its additional with solid floodplain ridges of sections, and are watertightly connected to the outlet bottom by means of a concrete threshold, the lower end of the pivot wall being equipped with a thrust sector, and from the side of the flood waters of the upper pool the pivot wall is provided with a support and a vertically variable draft of the upper head of the flood water level sides of the release through separate sections of the flooded dam into the storage tank.

The crest mark is made in separate sections of both the flooded and non-flooded sections of the dam and the crest, located at the same level as the main unsinkable dam, create a common front along the perimeter of the channel in the form of many outlets of rectangular cross section and they are selected from the distribution overflow flow rate towards the storage tank in the form of a channel. As a result of this, the direct overflow of water through the crest of the flooded dam is prevented.

Creating below an additional ridge in the form of many outlets with retaining walls installed through the ridge of the sections of the flooded dam, and the weight of each of them are selected by a hydraulic known calculation according to the hydraulics formulas, which provides the ultimate state of the wall to tip over to the side of the storage tank in the form of a channel when reaching the upper the draft of the specified water level from the side of the flood inlet over individual sections of the flooded dam with additional ridges are the difference from the prototype and the certificate UT about the novelty of the claimed technical solution.

The dispersion of the inlet stream into the storage tank in the form of a channel along its entire perimeter with the possibility of ensuring acceptable specific overflow costs through a retaining rotary wall with a non-washable speed ensures the preservation of the soil cover of the additional crest of its non-flooded sections and its slopes (walls). Thus, the releases of a rectangular cross-section with retaining rotary walls in the spring period, during the period of the flood, allow autonomous and automatic modes to provide sufficiently reliable protection against the destruction of the overflow sections of the embankment dam with increasing flow rate.

The implementation of a system of a similar design was not identified from the studied scientific and technical information and patent documentation, which allows us to judge the inventive step of the claimed technical solution.

In FIG. 1 shows a general diagram of a drainage and humidification polder system; in FIG. 2 is a section AA in FIG. one; in FIG. 3 - node I in FIG. 2; in FIG. 4 - node II in FIG. 2; in FIG. 5 is a longitudinal section with outlets between ridges of the overflow dam; in FIG. 6 is a diagram of the action of forces on a retaining wall, the moment of its ultimate action.

The drainage and humidification polder system includes drains 1, which are connected to the collector 2, and the last one to the main channel 3, at the mouth of which a pump station 4 is installed for pumping water from the polder system through the flood-free dam ditch 5 into the storage tank, made in the form channel 6, fenced from the water intake side of the flooded dam 7, made of an additional upper part of the flooded dam with ridges 8 at the same level as the crest of the main flooded dam 5. In dam 7, it is provided outlets 9 located between the ridges 8 along the normal to its horizontal plane of flooding, with a mark of this plane below the retaining structure 10 and enclosed from the sides and from the bottom by means of the outlet 9 of a rectangular cross section in concrete clothing made in the form of a threshold 11. The front of the outlets 9 is structurally divided into n sections of equal length along the entire perimeter of channel 6. At each individual section of release 9, a retaining structure 10 is constructed in the form of an overflow with a wide threshold, throughput Q _calc. / n = q, m ³ / s of each release.

For the flow q, the necessary filling head N is determined in front of the flooded sections of the dam 7 with additional non-flooded sections of its crest 8, the latter being located at the same level as the main flood-free dam 5 at Q _calculation. , determine the mark of the threshold 11 of the concrete clothing of each issue 9 along the perimeter of the dam 7 with the crest 8. Between the unsinkable ridges 8 of the dam 7, the releases 9 are made, the threshold 11 of which has concrete clothes and is provided with a rotary retaining wall 12 with a curved stop 13 installed with an inclination in the direction of the flood from the storage tank, made in the form of a channel 6 with an unsinkable dam 5 and unsinkable sections of the ridge 8 with the front of the outlets 9 of the dam 7, while the sections of the ridges 8 are separated by concrete thresholds 11 with releases 9. In addition, the retaining wall 12 through a sealing gasket (not shown) is waterproof connected to the axis of rotation 14 on the threshold 11.

, расстояние от центра тяжести - а стенки до ее упора в порог; угол - α, между стенкой и линией горизонта порога).From the side of the flood approach to the dam 7, the pivoting retaining wall 12 is provided with supports 15 and 16, the mark of the ridge 17 of the retaining wall 12 is located below the mark of the ridge 8 of the dam 7, and the weight of the wall 12 is selected by calculation using the well-known hydraulics formula (based on: volumetric weight of water - γ ; the width of the wall - B, wetted by water from the side of the flood at the moment of its extreme equilibrium; the length of the wall -

, the distance from the center of gravity - and the walls to its stop at the threshold; angle - α, between the wall and the threshold horizon line).

If the water level is exceeded during floods to a certain design time, a tilting moment is created that exceeds the holding moment from the weight of the retaining wall 12 (G), and the retaining wall 12 tilts due to the water pressure W relative to the axis of rotation 14 (point A in Fig. 6). A support 18 (for example, from a cable or fishing line) is attached to the support 15 from the flood waters, which is connected to the mark of the ridge 17 of the retaining wall 12 at the point of application of force to rotate the wall 12, which rotates towards the passage of water through the flooded sections of the dam 7 into the channel 6. The rod 18 experiences constant unwinding on the drum 19, placed on the lever 20, or can be made in the form of a flexible spiral with an adjustable length depending on the rotation of the wall 12, respectively, the wall 12 is equipped with a curved stop 13, placed against false side retention wall 12.

To control the water levels in the soil, a lower water outlet 22 is installed at the mouth of the water conduit 21 at the mouth of the conduit 21, and a downstream water outlet 23 is installed in the channel 6. The regulator draws water from channel 6 for humidification purposes. At the exit of the outlet 22, a portal wall 24 is installed to stiffen the conduit 21 and install the housing 25 of the downstream controller. In the housing 25 (FIG. 3), a throttle valve 26 is installed with a counterweight made in the form of a sector 27, and the valve 26 has an axis of rotation 28. The throttle valve 26 by means of a hinge 29 is connected to the beam 30, which has a rotation axis 31 in the center. A rod 32 is attached to the other end of the rocker arm 30, on which the float 33 is fixed. At the inlet of the water outlet 24, a regulator is installed, consisting of a housing 34 (Fig. 4), on which a throttle 35 with a counterweight made in the form of a sector 36, and a throttle are mounted 35 has an axis of rotation 37.

Drying and moistening polder system works as follows.

In the spring, when there is an excess of moisture in the soil, water from the control network 1 enters the collector 2, then to the main channel 3, and from the last it is pumped by the pumping station 4 and discharged into the channel 6, which at the same time is also filled with flood waters. The water level of the flood in the upper pool rises in front of the ridge 8 of dam 7 to a certain level, at which the rotary retaining wall 12 is tipped over by the water pressure W from the side of the flood water supply, creating a tilting moment from the weight G of the retaining wall 12 relative to the rotation axis 14 fixed in the concrete threshold 11. As the water overflows, the rod 18 continues to unwind on the drum 19 and the wall 12 rests with a stop 13 on the threshold 11, the rod 18 is completely unwound on the drum 19, and the rotary wall 12 continues to avatsya in the open position when the work all editions 9 that will especially be the case in the flood peak. At the end of the fall of the flood, the outlets 9 will be turned off in the reverse order, the rod 18 is wound on the drum 19 and completely wound on it, and the rotary retaining wall 12 rests with an inclination on the supports 15 and 16, while remaining in the closed position due to the constant twisting force drum 19 with a decrease in flood level, weakening with a decrease in water pressure W from the side of flood waters.

Varying the elasticity of the rod 18 on the drum 19, its location on the crest 17 of the rotary wall 12, you can adjust the opening height of the wall 12 with respect to the moment of weight G of the rotary retaining wall 12, which also ensures the attraction of the wall 12 to the supports 15 and 16 and tight the fit of the wall 12 to the side walls of the outlet 9 of a rectangular cross-section between the ridges 8 of the dam 7.

The described system design has a number of technical and economic advantages in comparison with the analogue. The difference is, first of all, in that it provides sufficiently reliable protection against flood waters and the destruction of the overflow dam with the help of a rotary retaining wall located in the outlet of a rectangular cross section between the ridges of the overflow dam in autonomous and automatic modes, even with slight differences in height between the opening and closing the retaining wall. In addition, it provides minimal damage to hydraulic structures and the environment while reducing the cost of erecting a flooded dam and hydraulic structures, limiting only to the initial costs of excavation and the construction of outlets between the ridges of the dam.

Claims (1)

A drainage and humidification polder system, which includes an unsinkable bunding dam, an accumulating tank, a collector-drainage network, a pumping station and a water inlet and is equipped with an additional flooded bunding dam laid parallel to the main accumulating tank, made flooded in the form of a channel laid between the dams and connected drainage network, characterized in that the ridge of the flooded dam is additionally made at the same height as the ridge of the main unsinkable yes MBA and is made in the form of a set below this ridge of outlets of rectangular cross-section, the common front of outlets is determined from the distribution of the estimated flow rate in front of the ridge with separate sections of the flooded dam, while the outlets of a rectangular cross-section are provided with a pivoting retaining wall mounted with an inclination to the side of the accumulating tanks from the outside of the exhaust through separate sections of the flooded dam located between its additional unsinkable ridges c, and are watertightly connected to the outlet bottom by means of a concrete threshold, the lower end of the turning wall provided with a thrust sector, and from the side of the flood waters of the upper pool the turning wall is provided with a support and a vertically variable draft of the upper pool of the flood water level from the outlet side through separate sections of the flooded dam in the storage tank.

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