BG64504B1 - Method and plant for waste water treatment - Google Patents

Abstract

The method and the plant find application for the treatment of chemically polluted wastewater from ore mines and from industry. By them, ecological and low-energy treatment of any quantities of wastewater is attained without releasing partially treated water after the plant. The plant comprises a structure (25) with solar-ray capturing walls between which vertical evaporation elements of rectangular shape are mounted, made in the form of evaporation panels (1). The latter are positioned in rows along length and width, and each panel (1) is engaged by a protection apron (2) connected to a protection chute bottom (3), mounted in an inclined chute (16). Each chute (16) ends in a common collection chute (15), limited between the evaporation panels (1) by means of passages (22). An indirect heat exchanger (8) for heating the wastewater is connected to a solar collector (11). Behind each of the rows of the evaporation panels (1), along their lengths, a protection plate (23) is envisaged behind which a pressing means (26) is fitted. In the front and end walls of structure (25), side wall ventilation valves (18) and air heaters are mounted. Above them, in height, temperature sensors (29), humidity sensors (30) and pressure sensor (31) are built-in. A heating-and-ventilation system is envisaged comprising air heaters (21), upper ventilation valves (19), fitted under the roofing (28), and the wall ventilation valves (18). The upper (19) and the wall (18) ventilation valves are connected to fans (20). Each and every elements of the heating and-ventilation system are controlled by computer (32).

Description

(54) METHOD AND INSTALLATION FOR POLLUTION WATER TREATMENT

Technical field

The invention finds application for the purification of contaminated water, in particular of chemically contaminated water from the sediment ponds of tailing ponds, sludges and other landfills, as well as radioactive waste contaminated water following the application of the methods of radioactive purification required by the regulations.

BACKGROUND OF THE INVENTION

A method of purifying contaminated water is known, in particular for the preparation of drinking water from water containing impurities, marsh water, tasteless water or water used for industrial purposes. The method involves the following sequence of operations: the contaminated water is first introduced into a heating chamber and then into a evaporation chamber, along which a network of embankments is formed along the bottom surface of which channels are formed. The embankments are made of capillary material. The contaminated water evaporates under the influence of direct solar energy and the pollution is deposited on the embankments. The water-saturated air is directed to the heat exchanger. The steam condenses and the resulting water is lowered down a stepped cascade until the embankments and channels are reached. The solar energy absorbed by the mounds causes the evaporation of water and the saturation of air with water vapor / 1 /.

The installation for the implementation of the method is built under a glass structure exposed to direct sunlight. Works in two cycles: air and water. Under the structure are formed sequentially a chamber for heating the water, a evaporation chamber, the floor surface of which is a network of embankments and channels between them. Each embankment is made of porous material. After the evaporation chamber there is a heat exchanger, from which the water flows down a stepped cascade, after which it floods the embankments and channels. Drainage pipelines, a pump and the necessary measuring and reporting equipment for them are provided / 1 /.

The known method is slow, complex, with two cycles, and installation is limited in terms of the spatial arrangement of its constituent elements.

A method of purifying contaminated water is known, in particular for seawater purification to obtain drinking water. This method involves the following sequence of operations: evaporation of preheated contaminated water is carried out in a confined space, which is pressurized and sprayed over vertically arranged rectangular evaporators and a stepped surface and subsequently discharged to a collecting chute. Contamination or sea salt is deposited along the stepped surface of the evaporation elements. By means of the provided aerometer and hygrometer, the parameters of the air are monitored, ie. maintenance of optimal air parameters in the enclosed space / 2 /.

An installation for carrying out the method is also known. It consists of a glass structure that houses vertical rectangular evaporators and a stepped surface. These evaporative elements are pressurized with preheated contaminated or salt water and are continuously poured through spray nozzles mounted on a pipe system above them. A collecting vessel with a pipeline is provided below them. The heated water can also be used for heating. Contaminants or salt are retained on the stepped surface of the evaporating elements when the installation is used to obtain seawater. The resulting sea salt is mechanically removed (2).

With the known method, it is impossible to quickly and accurately control and regulate the parameters of the air: temperature, humidity and pressure. The installation does not allow easy removal of the contaminants accumulated on the evaporation elements, especially when used for water treatment.

SUMMARY OF THE INVENTION

The problem is to create a method and installation for the purification of contaminated water, through which to achieve environmentally friendly and low-energy treatment of any water quantities of contaminated water, without letting the partially purified water into the water collectors after installation.

The problem is solved by a method of purification of contaminated water, in which the contaminated water is pre-heated, fed into a pressurized enclosure and sprayed over rectangular vertical evaporators until evaporation, after which residual and condensed water is discharged below them. to the collecting chute, while controlling the parameters of the air in the enclosed space.

According to the invention, the evaporation elements are in the form of flat evaporation panels, and the evaporation of the contaminated water is regulated by controlling and simultaneously controlling the air parameters: temperature, humidity and pressure, or by controlling and separately controlling each of the air parameters: temperature, humidity and pressure.

The problem is also solved by an installation for the implementation of the method, including a closed space in the form of a structure with sun-catching walls, between which are mounted vertical evaporators with rectangular shape, above which are located spray nozzles connected by a pipe system with a pump, and below they are provided with a collecting chute. The installation also includes an indirect heat exchanger for heating contaminated water, valves and electronic controls.

According to the invention, the rectangular vertical evaporators are designed as evaporator panels arranged in rows in length and width, each evaporator panel being enclosed by a protective apron connected to a protective seafloor mounted in an inclined groove. Each inclined chute ends in a common collecting chute bounded between the evaporation panels by passageways. The indirect heat exchanger for heating the contaminated water is connected to a solar collector. A protective plate is provided behind each of the rows of evaporation panels along which a press means is located. In the front and back walls of the structure are mounted side wall ventilation valves and heaters, above which, in height, are built in temperature sensors, humidity sensors and pressure transducer. A ventilation system consisting of heaters, upper ventilation valves and side wall ventilation valves is provided. The valves are connected to fans and are generally computer controlled.

In a variant embodiment of the installation, each of the rows of evaporation panels along the length and width of the enclosed space of the structure are separated as separate modules.

The advantages of the invention are that thanks to the lightweight construction with sun-catching walls, the purification of contaminated water is a low-energy and inexpensive process. The installation is made of fast-assembled and disassembled elements, thanks to which the evaporation panels with the adhering contaminants on them allow easy and quick pressing, packaging and removal to the storage or disposal site. It is because of these possibilities that the process is extremely eco-friendly, as the waste from chemically polluted water does not cause environmental damage. Purification of various water quantities of contaminated water is also achieved by increasing or decreasing the area of the evaporator panels, the efficiency of the thermal insulation of the structure and the area of the solar collectors. The greater the amount of contaminated water and the less purification time, the greater the area of the evaporation panels. In all seasons, except winter, the cost of evaporating water and purifying it is minimal, since solar energy is the main source of energy. An important advantage of the invention is that, after purification of the contaminated water, there is no residual part of it which is to be discharged into the environment, therefore there is no additional pollution. The contaminated water evaporates completely, which is why care is taken to comply with the costly and difficult to reach requirements for the category of water intake in which the treated water is usually discharged. The process of evaporation and purification of contaminated water is fully automated, with continuous control and management of the air parameters: temperature, humidity and pressure in the enclosed space below the structure. By controlling the parameters of the air, the values of which are recorded continuously, but according to the specific requirements and the specific natural conditions and through the provided heating and ventilation system, each of the parameters of the air can be changed. The installation can be located directly in or near the tailings pond or near the sludge pond and does not require new terrains.

Explanation of the annexed figures

The invention is shown in the accompanying drawings, of which:

Figure 1 shows a front view of an installation according to the invention;

Figure 2 is a section through AA of Figure 1 according to the invention;

Figure 3 is a sectional view on BB of Figure 1 according to the invention.

Examples of carrying out the invention

The method of purifying contaminated water involves the following sequence of technological operations: the contaminated water is preheated, fed into a pressurized enclosure and sprayed over rectangular vertical evaporating elements until evaporated, after which residual and condensed water is discharged below them. collecting chute, while controlling the parameters of the air in the enclosed space.

According to the invention, the evaporation elements are in the form of flat evaporation panels 1, and the evaporation of the contaminated water is regulated by controlling and simultaneously controlling the air parameters: temperature, humidity and pressure, or by controlling and separately controlling each of the air parameters: temperature , humidity and pressure.

The installation for implementing the method is depicted in the attached Figs. 1,2 and 3. The installation includes a structure 25 with sunbathing walls. Inside the enclosed space of the structure 25, rectangular vertical evaporation elements, designed as evaporation panels 1, arranged in rows in length and width, are mounted. Each evaporator panel 1 is covered by στ protective apron 2 connected to a protective groove bottom 3. Evaporator panels 1 are secured in rows in length in support frames 4. Above each of the rows of evaporator panels 1 are spread nozzles 5 connected by tubes 6 with a pump 7 and an indirect heat exchanger 8 to heat the contaminated water in which the coil 9 is mounted. The front end of the coil 9 is connected by an inlet pipe 10 to a heating fluid with a solar collector 11, and the other end of the coil 9 is connected to the solar wheel. ector 11 through an outlet line 12 and a control pump 24. Each safety bottom 3 is mounted in a sloping chute 16 terminating in a common collecting chute 15 bounded between the evaporation panels 1 by passages 22. In the lowest part of the collecting chute 15 is mounted a circulation pump 13 and a discharge pipe 14 through which the unpaired contaminated water is fed to the indirect heat exchanger 8, in which it is mixed with the newly received contaminated water through an inlet pipe 17 for contaminated water. Behind the rows of the evaporator panels 1, a common protective plate 23 is provided along the length. In an additional annex 27 of the structure 25 there is a press means 26. In the front and back walls of the structure 25 side wall ventilation valves 18 and heaters 21 are installed above, which, in height, are built-in temperature sensors 29, humidity sensors 30 and pressure sensors 31 associated with the intended heating and ventilation system. The ventilation system consists of heaters 21, upper ventilation valves located in the roof portion 28 of the structure 25 and wall ventilation valves 18 located on the side walls of the structure, with all the upper 19 and wall valves 18 connected to the fans 20 and are generally computer controlled 32.

In a variant embodiment of the installation, each of the rows of the evaporator panels 1 in length and width of the enclosed space of the structure 25 are separated as separate modules.

Application (use) of the invention

The method and installation for the purification of contaminated water according to the invention are extremely effective in the treatment of water in the sedimentary lakes of tailings ponds, sludges and other landfills of chemically contaminated water, as well as waste water from mines and waste chemical polluted industrial waters. As the content of sludge and contaminated water is continuously checked and controlled, the baseline values and preconditions under which the invention is applied are always known. This makes it possible to determine both the geometric dimensions of the structural elements of the installation and to determine the preliminary values of the air parameters. Depending on the natural conditions of the area in which the installation will be installed, as well as the current meteorological values of the air parameters, the installation provides the possibility to control by measuring and reporting data on the values of the air parameters: temperature, humidity and pressure and control of these parameters, i. changing the values of the air parameters simultaneously or separately by switching on or off the respective elements of the heating and ventilation system. If necessary to reduce air humidity, fans 20 are switched on, wall valves 18 are opened, heat sinks or other similar predefined actions stopped or modified to change the corresponding value of the monitored air parameter. When it is necessary to speed up the process, the temperature parameter rises and the pressure parameter decreases, which makes evaporation faster. In this way, it is actually through the installation that each of the air parameters, temperature, humidity and pressure, is simultaneously or separately controlled. The optimal water flow rate and the optimal values of the air parameters are known in advance. The optimization and management of the values of air parameters: temperature, humidity and pressure depend on the specific application conditions that change every day.

The use of solar energy for the evaporation of polluted water provides an efficient, inexpensive and environmentally friendly production process.

Contaminated water is supplied from its inlet pipe 17 into the indirect heat exchanger 8 for heating, and then is pumped through the pump 7 through the pipes 6 to the nozzles. Spilled contaminated spilled water evenly and continuously pours the evaporation panels 1 on all sides. The evaporation panels 1 are made of lightweight material that quickly absorbs solar energy. Due to the absorbed solar energy, the surface of the evaporation panels 1 is at a very high temperature. Sprayed contaminated water flows into the evaporation panels 1 and, due to the high surface temperature, evaporates rapidly and the contaminants remain on the surface of the evaporation panels 1.

The water which has not evaporated or the water used to flush the evaporation panels 1 is discharged into the protective drainage basins 3 and from there into the common collecting chute 15. Through the circulation pump 13 and the discharge pipeline 14, the unpaired water from the common collecting chute 15 feeds back into the indirect heat exchanger 8, in which it is mixed with the newly received contaminated water to repeat the cycle.

The evaporation panels 1, after filling them with the contaminants adhering to them, move to the press 26, and from there - for packaging and transport to the storage site.

Claims (3)

Claims 1. A method for the purification of contaminated water, in which the contaminated water is preheated, fed into a pressurized enclosure and sprayed over rectangular vertical evaporating elements until evaporated, after which residual and condensed water is discharged below them to a collecting chute. , while controlling the parameters of the air in the enclosed space, characterized in that the evaporating elements are in the form of flat evaporating panels (1) and the evaporation of the contaminated water is -regulated by control and simultaneous control of air parameters: temperature, humidity and pressure, or by a control and individually control each one of the parameters of air: temperature, humidity and pressure. 2. Installation for implementing the method, comprising a closed space in the form of a structure with sun walls, between which rectangular vertical evaporators are mounted above which are spray nozzles connected by a tubular system with a pump and provided below collecting chute, as well as indirect heat exchanger for heating contaminated water, valves and regulating electronic elements, characterized in that the vertical rectangular evaporators are designed as vapors Our panels (1) are arranged in rows in length and width, with each evaporator panel (1) covered by a protective apron (2) connected to a protective bottom (3) mounted in a sloping chute (16) ending in a common collecting chute (15) bounded between the evaporation panels (1) by passageways (22), wherein the indirect heat exchanger (8) for heating the contaminated water is connected to a solar collector (11) and behind each of the rows of the evaporation panels (1) ), a safety plate (23) is provided in length, behind which a press means (26) is located, such as in one and the rear wall of the structure (25) are fitted with side wall ventilation valves (18) and heaters (21) above which, in height, there are built-in temperature sensors (29), humidity sensors (30) and a pressure sensor (30). 31) associated with the intended heating and ventilation system, consisting of heaters (21), upper ventilation valves (19) located under the roof (28) and wall ventilation valves (18), wherein the upper (19) and wall vents ventilation valves (18) are connected to fans (20), with all elements of the heating-vent the ilation system is computer controlled (32). 5 Installation according to claim 2, characterized in that each of the rows of the evaporation panels (1), along the length and width of the enclosed space of the structure (25), are separated as separate modules.