RU2693735C1 - Pond-evaporator of mineralized drainage flow - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to irrigated agriculture and will find application in utilization of mineralized drain flow of irrigation and reclamation systems. Pond-evaporator of mineralized drainage flow is connected by means of water regulating structures with supply channel, is divided into compartments, equipped with system of vertically installed wind-guiding partitions and device for direction of air flow to water surface. Compartments are equipped with structural modules arranged within pond-evaporator compartments and on its bank, and contain support frame with beams, on which evaporation elements in form of spiral of screw from hydrophilic open-porous material are vertically fixed. Pump station is installed on pond bank, pressure pipeline of which is connected to distributing pipelines laid along beams and equipped with water outlets at each evaporation element. Besides, support frame of each structural module can be arranged on foundation blocks above surface of water or shore, each evaporation element can have black colour or close to it by reflecting ability, and in lower part of evaporating element can be mounted device for collection of salts. Structural module located on the shore is equipped with a system of return water withdrawal into pond-evaporator compartments.

EFFECT: proposed design of pond-evaporator provides intensification of evaporation process due to increased area of evaporating surface and improvement of heat-and-energy sharing between air flows and moistened evaporation elements.

4 cl, 8 dwg

Description

The alleged invention relates to agriculture, in particular to irrigated agriculture, and will find application in the disposal of saline drainage drainage systems. In addition, it can be used in the evaporation of wastewater of various genesis, the mineralization of which is formed mainly by mineral salts.

Known pond-evaporator drainage drain associated with the supply channel through regulatory structures, on the surface of which are floating plates with through holes and inserted in them acceleration evaporation from a hydrophilic capillary-porous material. The evaporation pond is divided by jumpers into the compartments of the intensified evaporation, which are hydraulically connected with each other and the inlet channel. At the corners of the floating plates, holes are made through which the vertical rods with a length exceeding the depth of the maximum filling of the compartments, provided with locks for the upper and lower positions of the plate, are inserted through the bottom of the compartments. Each floating plate has a coating of hydrophilic capillary-porous material, made with a protrusion beyond its lower surface. In addition, the evaporation pond is equipped with additional compartments for the accumulation and evaporation of wash water (US Pat. RF. No. 2515041, IPC E02B 11/00, C02F 1/14, publ. 2014, Bull. No. 13).

The disadvantages of this evaporation pond are the significant costs of materials used in the manufacture of elements to increase the area of the evaporating surface, the difficulty of removing salts from the surface and near-surface layers of elements from porous and capillary-porous materials.

The famous evaporation pond of mineralized drainage flow is connected by means of water control structures with a supply channel and equipped with floating evaporation elements from a hydrophilic capillary-porous material. Floating evaporating elements are made in the form of hollow perforated drums coated with hydrophilic capillary-porous materials, fixed between two supporting floats so that they can rotate around their horizontal axis using end axes attached to the sleeves placed along the length of the floats and equipped with a mechanism of their 180 ° synchronous rotation and back. (US Pat. RF No.2527041, IPC Е02В 11/00, C02F 1/14, published 2014, Byul. No. 24).

The disadvantages of this technical solution include the possibility of mechanical and biological clogging of accelerators of evaporation of drums with a coating of capillary-porous material during their operation, reducing its adsorption properties; lack of efficiency due to shielding of the surface of the compartments with floating evaporating elements that prevent water from heating by solar radiation.

Closest to the proposed device is a pond-evaporator drainage flow, connected by means of water control structures with a supply channel and divided into compartments, located in a cascade. The evaporation pond is equipped with a system of wind-guiding partitions, main and additional, representing a structure of vertically installed and fastened together panels. The main partitions are located radially to the banks of the pond, and additional - between them at right angles to the coast. The evaporator pond is additionally equipped with a device for directing the air flow to the water surface consisting of panels installed along the coastline with the possibility of tilting in a vertical plane towards the water surface of the pond (US Pat. RF No. 2528006, IPC Е02В 11/00, publ . 2014, Bull. No. 25).

The disadvantages of this evaporation pond include the low evaporation efficiency of drainage flow due to the use of only one active factor — an increased air flow rate, an evaporating surface area equal to the contact surface of water and air, is limited by the size of the evaporation pond and remains almost constant, and the contact itself occurs with a parallel flow of air masses above the water mirror.

Eliminate these drawbacks allows the proposed pond-evaporator mineralized drainage flow associated through water control structures with a supply channel, divided into compartments equipped with a system of vertically installed wind guide walls and a device for directing air flow to the water surface, in which, according to the invention, the compartments are equipped with structural modules, located within the compartments of the evaporation pond and on its bank, and containing a support frame, with beams, on which The evaporation elements in the form of a spiral of a screw from a hydrophilic open-porous material are mounted vertically, while a pumping station is installed on the bank of the pond, which is connected to distribution pipelines along beams and provided with water outlets at each evaporation element. In addition, the support frame of each structural module is placed on the foundation blocks above the surface of the water or shore, besides each evaporator element has a black color or close to it in reflectivity, and a device for collecting salts is mounted in the lower part of the evaporation element, and the constructive module, located on the shore, is equipped with a system for diverting return water to the compartments of the evaporation pond.

A new technical result from the proposed invention is that supplying the pond with structural modules with evaporation elements in the form of a spiral auger from a hydrophilic open-porous material in combination with wind-guiding partitions and supplying drainage water to the surface of a spiral auger from the outlets provides for an intensification of the evaporation process by increasing the area of the evaporating surface and improve heat and mass transfer between the air flow and humidified evaporation elements, forms which ensures the independence of the evaporation intensity on the wind direction.

The invention is illustrated by drawings, where: in FIG. 1 is a schematic diagram of a pond-evaporator drainage flow, view in plan; in fig. 2 shows a longitudinal section A-A in FIG. one; Fig 3 is a schematic diagram of a constructive module for the intensification of evaporation (plan view); in fig. 4 is a longitudinal D - D section of FIG. 3; in fig. 5 is a diagram of the return water removal system from structural modules for evaporation intensification, located on the shore, into the compartments of the evaporation pond; in fig. 6 - selection of salt NaCl on the surface of the model of the evaporator element from a capillary-porous material (photo). in fig. 7 is a cross-sectional section B in FIG. 1 wind guide walls; in fig. 8 is a transverse B-B section in FIG. 1 device for regulating the direction of air flow in the vertical plane.

The evaporator pond is connected to the drainage collector by the inlet channel 1, which takes command position relative to the pond, separated by lintel 2, equipped with a culvert 3, into compartments 4 and 5 arranged in a cascade (Fig. 1 and 2). Compartment 5 is equipped with a discharge pipe 6 with a valve.

On the banks of the pond installed wind control system, which includes the main partitions 7, radially located towards the compartments 4, 5 of the evaporation pond, and additional partitions 8, installed between the main at right angles to the banks of the evaporator pond. A device 9 is mounted along the coastal strip of the evaporation pond to direct the air flow to the surface of the water.

The partitions 7, 8 (fig. 1) of the wind-guiding system consist of panel structures, which are bonded sheets 10 of durable material, mounted vertically with the help of supports 11 and stretch marks 12 with anchor fixture 13 (fig. 7). In the steppe areas of the arid zone, the length of the partitions can be 50 - 70 or more meters with a height of 5-7 meters.

The device 9 along the coastline for directing the air flow, concentrated by the wind guide system, to the surface of the pond, consists (Fig. 8) of panels 14 placed on supports 15 and equipped with a system of cables 16 with anchors 17 that allow panels 14 to be tilted in a vertical plane side of the water mirror of the evaporator pond. The angle of inclination of the panels 14 to the water mirror is tgα = H / L, where H is the height of the placement of the panels on the support; L - distance from the support to the opposite shore.

Within the compartments 4 and 5 of the evaporation pond and on its banks (Fig. 1), structural modules 18 and 19 for the intensification of evaporation, hydraulically connected by means of the distribution network of pipelines 20 to a pump station 21 with water intakes from compartments 4 and 5, are preferably evenly placed.

Constructive modules for the intensification of evaporation within compartments 4, 5–18 and ashore — 19 (FIG. 4) contain a support frame 22, for example, in the form of a parallelepiped, located above the water surface or the ground surface on the foundation blocks 23, evaporation elements 24 spiral worm (Fig. 5), mounted vertically on the beams 25 and hydraulically connected to the distribution network of pipelines 20 and pumping station 21 through a system of supply pipes 26, outlets 27 and supply tanks 28.

The spiral of the screw 29 in the lower part is equipped with a device for collecting salts, made in the form of a segment of a rectangular strip 30 with a capacity of 31 (Fig. 4).

Each water outlet 27 supplies water to tank 28 in a volume that provides wetting of the auger coil 29. Each supply tank 28 has the appearance of a cylindrical cup, in the bottom of which there are a number of holes (not shown) evenly distributed along the bottom radius of the tank 28 to moisten the auger spiral 29.

The salt collector tank 31 has a bottom perforation for brine flow, they are installed within the lower belt (not shown) of the support frame 22 under each evaporation element 24, capturing the area under the element 30 of the auger spiral 29.

Constructive module 19 for the intensification of evaporation within the bank of the evaporation pond has a similar design and is supplemented by a system for diverting return water to compartments 4 and 5 (Fig. 5) in the form of a recessed receiving tank 33 under each module and its associated branch pipe 34.

The evaporation pond of the drainage flow functions as follows: During the operation of the irrigation and drainage systems (April - October for the irrigated agriculture zone of the South European part of the Russian Federation), the mineralized drainage flow from the collector flows through channel 1 to compartment 4, where it evaporates and bypasses through the conduit structure 3 in lintel 2, in compartment 5, located lower in the cascade, and in compartment 4, a fresh portion of drainage flow is supplied. In compartment 5, further concentration of drainage flow occurs. The resulting concentrated solution is discharged from the evaporation pond through line 6 when the valve is opened. During the warm period of the year, the cycle of filling, concentrating by evaporation and diverting concentrated drainage flow is repeated several times.

The intensification of evaporation as a result of increasing the speed of the air flow is provided by the main partitions 7 of the wind-guiding system located radially to the evaporator pond. They carry out the concentration of the air flow and increase its speed over the surface of the water in compartments 4 and 5. The stabilization of the required direction of the concentrated air flow is provided by additional partitions 8 placed between the main 7 at right angles to the banks.

To increase the turbulence of the movement of air flow directly above the water surface of the pond and within the constructive modules 18 are panels 14, mounted on supports 15 along the coastline of the pond.

The pumping station 21 takes the saline water from the compartments 4, 5 and via the distribution network 20 supplies it to the design modules 18 and 19 for the intensification of evaporation. Within the modules 18 and 19, the water through the piping system 26 through the outlets 27 enters the feed tanks 28 and then through the holes in the bottom of the tanks 28 (not shown) to the upper part of the surface of each spiral of the screw 29 of the evaporation element 24, moistening the spiral of the screw 29 and creating conditions for intensive evaporation of water in all directions of the wind.

Depending on the task: a) mainly the concentration of brines; b) obtaining salts and concentration of brines, use a different nature of moistening of the evaporation elements 24 in time - constantly (task “a”) and periodically (task “b”). The return water in both cases is discharged back into compartments 4 and 5.

Receipt of salts in the tank 31 is provided as a result of shedding elements 29 and 30 from the surface under the action of gravity and wind forces - FIG. 6

As the tanks are filled, the salts are mechanically removed, dehydrated with a centrifuge, dried, crushed, packed in a waterproof package and stored for future use.

Thus, supplying the pond with structural modules with evaporative elements in the form of a spiral of a screw from a hydrophilic open-porous material in combination with wind guiding partitions and supply of drainage water to the surface of a spiral of a screw from the outlets, increases the evaporation surface area and improves heat transfer between air flows and humidified evaporation elements, the shape of which ensures the independence of the evaporation rate from the direction Lenia wind.

Claims (4)

1. Evaporator pond of mineralized drainage flow connected by means of water regulating structures with a supply channel, divided into compartments equipped with a system of vertically installed wind-guiding partitions and a device for directing the air flow to the surface of water, characterized in that the compartments are equipped with design modules located within the compartments pond-evaporator and on the shore, and containing a support frame with beams, on which the evaporation elements in the form of a spiral auger and hydrophilic open-porous material, wherein a pond installed pump station, which pressure line is connected to the distribution pipes, laid on the beams and provided with discharge outlets each evaporating element. 2. Evaporator pond according to claim 1, characterized in that the support frame of each structural module is located on the foundation blocks above the surface of the water or shore. 3. Evaporator pond according to claim 1, characterized in that each evaporating element has a black color or close to it in reflectivity, and a device for collecting salts is mounted in the lower part of the evaporating element. 4. Evaporator pond according to claim 1, characterized in that each structural module located on the shore is equipped with a system for diverting return water to the compartments of the evaporator pond.

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