SE536438C2 - Water purification system - Google Patents

Abstract

System (1) for the treatment of water including at least one first subsystem (2) for coarse separation of impurities from the water, at least one second subsystems (3) for the addition of precipitation chemicals to the water and at least one third subsystem (4) for biological treatment of the water and sedimentation (4) from the water. Unique to the present system is that the input of precipitation chemicals in the second subsystem takes place in a multitubular reactor (6) with at least one tubular coil (12) with at least one curved leg that is U-shaped, and that the first subsystem (2) and the second subsystem (3) fully or partially are enclosed or essentially enclosed in transportable units or modules.

Description

535 438 many cases not possible to perform. The mobile water purification systems that exist today are either limited to substantially small volumes of water or only form a sub-process in the overall water purification process.

It is also a problem to move components from a manufacturer to the place where it is to be used. Poor roads and other deficient infrastructure in many developing countries make it necessary for treatment plants to fit into standardized transport systems in order to be able to move more easily to the place where the plant is to be installed. It is also important that the system is as complex as possible to minimize the risks of incorrect mounting.

An additional problem with existing systems is that they are energy-intensive. Especially in developing countries, the availability of energy, or the cost of energy, can be a problem.

An example of an energy-intensive element in existing types of treatment plants is that these usually require some form of stirrer or mixing equipment in order for the added chemicals to be mixed in the required manner with the water to be treated. A more cost-effective (energy-efficient and drier safer) way of mixing and dissolving these chemicals in the water is preferable. There is therefore a need for a purification device and method that requires a relatively small supply of energy to purify the water.

A method and a device for shielding a limited water area in seas, lakes, rivers, major rivers and dams are already known via patent specification SE50491 1. The technology described in the patent specification constitutes only a subsystem for purification and therefore does not constitute a movable system for purification of water in accordance with the present patent application.

The described problems are solved, or reduced, with a construction according to the claims. OBJECTS OF THE PRESENT INVENTION The main purpose of the present invention is to create a system for purifying water which is cost effective to construct and use. It is a further object of the present system to create a system for purifying water which can be transferred to the user in standardized enclosures such as containers. It is a further object of the present invention to create a system which can be easily moved from one place to another. It is a further object of the present patent application to create a system for purifying water which uses geographical area in an efficient manner, i.e. 538,433 does not take up much space. It is a further object of the present invention to create a system in which a mixture of precipitating chemicals and the contaminated water can take place efficiently without additional agitation equipment. It is a further object of the present water purification system to create a system which requires as little energy as possible to achieve a satisfactory function.

Brief description of the figures referred to in the following paragraphs In the following detailed description of the present entry, reference and references to the following figures will be made. These are briefly described in the following ur gur list. The embodiments exemplified in the foregoing are not limiting of the scope of protection of the present patent application. Note that the fi gures are schematic and that details can thus be omitted in these.

Figure 1 shows a system in accordance with the present invention.

Figure 2 shows the chemical step second step.

Figure 3 shows the chemical addition of the second stage in a second view seen from above.

Figure 4 shows the chemical addition of the second stage in a third view from the short side.

Detailed Description of the Present Invention Referring to the figures, there is shown a system 1 for purifying water in accordance with the present patent application. System 1 comprises at least three subsystems. In the first subsystem (step) 2, a coarse separation of coarser impurities and the like takes place. In the second subsystem (step) 3, a precipitation of precipitating chemicals and the like takes place to the water to be purified. In the third subsystem (step) 4 a sedimentation of the pollutants in the water to be purified takes place. In this step 4, a biological purification of the water can also take place.

The contaminated water is fed to the first subsystem 2 in a manner suitable for the purpose.

For example, the polluted water can be fed to the water treatment plant via at least one pipeline, hose or the like. In the first step 2 of the system, a physical coarse separation of contaminants (not shown in fi gures) from the water takes place.

The first step 2 can be divided into two or two sub-steps. In the first step 2, a physical separation of coarser contaminants (not shown in figures) and the like takes place from the water.

The contaminants are preferably separated by means of at least one grid, a net, a screen or the like. By gross contaminants is meant contaminants which are physically separable with the grid, net, screen or similar device. The coarser contaminants are separated from the contaminated water in one or more steps. At steg your steps, for example, the separation can take place via two or fl your grilles, something, screens or the like. In the case of several grids, or the like, the grids, or the like, preferably have different mesh sizes or the like. The water is first passed through the coarsest mesh size, although the water is passed through any finer mesh sizes. After the contaminants are separated from the contaminated water by the sieve (s), or the like, the coarsely separated contaminants are moved to one or more containers or the like. In order to reduce the volume and weight of the coarsely separated contaminants, the separated coarser contaminants are preferably dewatered and compacted. The separated contaminants are removed after dewatering and possible compaction via, for example, a screw conveyor or the like to at least one container, bag, space or other similar collection space or place suitable for the purpose.

The container, bag or the like may conveniently be placed in the container or in a separate additional container or the like next to the first container. As the volume of the separated exceeds a certain volume, the separated one is moved to another place suitable for the purpose.

In the simplest form, the first subsystem 2, with which a coarse separation of contaminants from the water takes place, is enclosed, or substantially enclosed, in at least a first releasable unit such as a first container. In alternative embodiments, it is conceivable for the step to be performed in a number of different removable units, such as, for example, in a number of containers. The displaceable unit in the embodiment shown consists of a standard container such as a 20 or 40 foot ISO container or the like. By using standard containers as a removable unit, it is possible for the system's constituent subsystem to be easily moved from one place to another.

After the coarse separation, the first subsystem 2 transfers the partially purified water to the second subsystem via at least one pipe, hose, duct or the like. The transfer of water from the first subsystem to the second subsystem can preferably take place by self-pressure.

The self-sufficiency is achieved by placing the first subsystem 2 at a higher level than the second subsystem 3. Alternatively, the transfer of liquid from the first subsystem to the second stage can take place via pumping or with other learning technology for the purpose. In alternative embodiments, it is conceivable that the movement of water (liquid) takes place with a combination of self-pressure and pumping. 536 438 The second step 3 consists of a step for supplying precipitating chemicals and the like to the water. Step 3 may be divided into two or more sub-steps. The second subsystem 3 is preferably enclosed or substantially enclosed in at least one movable unit such as a standard container or another container suitable for the purpose. In alternative embodiments, it is conceivable that the movable unit consists of another movable unit suitable for the purpose.

In the second subsystem 3 a precipitation chemical, precipitation chemicals and the like are supplied to the water from at least one container 5. In the exemplary embodiment shown in the diagrams, precipitation chemicals are supplied from at least one first container 5 and at least one second container 5. If a container is used For example, weight distribution in containers can be unfavorable and cause problems when, for example, moving containers. In the embodiment shown in Figures, the problem of weight distribution has been solved by using two containers 5 for precipitating chemicals. A corresponding technical effect regarding even weight distribution can also be achieved if än your more than two containers S are used, provided that these are positioned in the container so that an iron weight distribution is obtained.

Unique to the present system is that the mixing of precipitating chemicals takes place in at least one tubular reactor 6 in which the chemicals are supplied to the water in the tubular reactor 6 by means of at least one metering pump 7 (or supplied in another way) which is controlled by at least one control system 8. the contaminated water (liquid) to the pipe reactor 6 takes place via at least one inlet 9 which is connected to the first subsystem 2 via at least one pipe, hose, duct or the like. The discharge of liquid from the tube reactor takes place via at least one outlet 10 which connects to the third stage 4.

The system 1 further comprises at least one fate meter 11 with which the fate in the tube reactor can be measured. The amount of precipitating chemicals is controlled by the measured fl fate. The precipitating chemicals may be, for example, aluminum sulphate (ALG), ferrous aluminum sulphate (AVR), polyaluminum doloride (PAX) or other precipitating chemical or precipitating chemicals suitable for the purpose. The amount of precipitating chemical or precipitating chemicals added to the water may vary within the scope of the present patent application. For example, the content of ferrous aluminum sulphate can amount to about 250 grams per cubic meter. Other parameters can also be measured and used as detailed information to the control system and for the regulation of the added amount of precipitation chemicals. The design of the control system may vary within the scope of the present patent application. The tubular reactor 6 consists of at least one first tube which is drawn in one or more loops 12. In the exemplary embodiment shown in the tubes, the tubular reactor 6 comprises a number of loops 12 of tubes. Although the number of loops in the figure shown is four, the number of loops can vary greatly within the scope of the present patent application. The respective pipe loop 12 preferably has at least one section, preferably del your sections, which have at least one shape, preferably several shapes which are suitable for the purpose of mixing water (liquid) and precipitating chemicals. The respective pipe loop 12 has, for example, at least one section, preferably your sections, which is substantially curved or has another suitable curved shape such as a U-shape, which has been found to have unexpected and favorable technical effects. An effect of pipe loops l2 with curved sections consists, for example, in that the supplied chemicals are mixed as required with the water without the need for additional pipe stirring equipment. This streamlines the entire system thanks to the fact that energy is saved when no extra energy-intensive stirring equipment is needed, while at the same time the reliability is improved by requiring fewer moving mechanical parts to obtain an appropriate mixture of the chemicals with the water. The design of the tube reactor 6 means that an efficient mixture of water and various precipitation chemicals takes place in the tube reactor in an energy-saving and reliable manner. In alternative embodiments, however, the loops may have a different shape suitable for the purpose.

In the exemplary embodiment, the tubular reactor 6 is located in the lower part of the container, such as for example on the bottom of the container. In the embodiment shown, the tubes of the tubular reactor are substantially horizontal (parallel to the bottom of the container).

In alternative embodiments, however, the pipe loops may be located in other positions suitable for the purpose in the container. Furthermore, the direction of the loops may deviate from the substantially horizontal direction.

After the second stage 3, the water is transferred from the second stage 3 to the third stage 4 via at least one pipe, hose, duct or the like. The transfer of the water from the second stage 3 to the third stage 4 can take place, for example, by self-pressure by placing the second stage 3 at a higher level than the third stage 4. Alternatively, for the transfer of liquid from the second stage to the third stage take place via pumping or with other technology suitable for the purpose. In alternative embodiments, it is conceivable that the movement of water (liquid) takes place with a combination of self-pressure and pumping. In further alternative embodiments, it is further conceivable that another technology suitable for the purpose is used.

The third step 4 consists of a step for biological purification and sedimentation of the water. The step for biological purification preferably takes place in a delimited (limited) water body area in seas, lakes, 536,438 rivers, larger rivers or the like. In alternative embodiments, it is conceivable that the step for biological purification and sedimentation takes place in a pond built on land adjacent to a watercourse.

It is conceivable that a system in accordance with patent specification SE504911 is used for the sensing of the limited water area. It is further conceivable that the system has an amran for the purpose suitable construction for cutting off the limited water area.

In the exemplary embodiment, the confinement of the limited water area takes place with at least one or more screen walls which are arranged and designed so that they can be placed standing in water with the upper edges of the walls above the water surface and with the lower edges of the walls anchored to the seabed.

The shield is in the application intended to be used as a sedimentation mandrel and is therefore divided into sections by means of a number of partitions. Each partition wall comprises at least one opening through which a flow of water can take place between one section to another section. Preferably, the openings in the partitions are located so that they are located on every other partition wall at one end and in every other the opening is located at the other end of the partition wall. This means that fl the fate of water takes place, for example, in a serpentine-shaped channel in the sensing. In alternative embodiments, the partitions are shorter than the width, or alternatively the length of the sides of the screen. By placing zigzag partitions, a serpentine-shaped channel can be formed. At one end of the serpentine-shaped channel, water is introduced, for example via at least one pipe or the like. At the other end of the serpentine channel there is at least one outlet through which the water fl flows out of the serpentine channel to the surrounding water.

During its passage through the serpentine canal, the water is purified by successive sedimentation of sludge, pollutants and heavier particles.

The screen walls are preferably made of some form of visible and waterproof material.

The material in the screen walls can, for example, consist of synthetic rubber, plastic, woven plastic or the like. It is further conceivable that other materials suitable for the purpose are used in the screen walls. The screen walls comprise in their upper edge, or in connection with the upper edge of the screen walls, at least one and preferably a number of surface bodies. The floating bodies cause the screen walls to extend at least to some extent a little above the water surface.

The screen walls also have anchoring means towards the seabed. The anchoring means may be the sink or the like. The sinks may consist of weights of concrete or other material suitable for the purpose 536 438. In the alternative embodiment, the anchoring means towards the bottom can be constituted by another anchoring means suitable for the purpose.

In alternative embodiments, the seabed may be completely or partially covered with at least one layer of material.

In further alternative embodiments, it is conceivable that each container, alternatively another enclosure, is provided with solar cells, smaller wind turbines or the like that can help to ensure the supply of electrical energy for the operation of the plant.

In the detailed description of the present invention, structural details may be omitted which will be apparent to one skilled in the art to which the method and apparatus relate. Such obvious design details and sub-procedures are included to the extent necessary to obtain a proper function for the present method and device. Although certain preferred embodiments have been shown in more detail, variations and modifications of the method and apparatus may be apparent to those skilled in the art to which the invention pertains. All such modifications and variations are considered to fall within the scope of the appended claims.

Advantages of the Invention With the present invention, a number of advantages are achieved. The most obvious is that a cost-effective system for purifying water is obtained. Another advantage of the present invention is that a replaceable system for purifying contaminated water is obtained. A further advantage of the present invention is that the water purification system can be pre-transferred in pre-transferable units such as in standard containers. An even further advantage of the present invention is that the water purification system is energy efficient and thus usable in areas with little energy supply, no energy supply or unreliable energy supply. Furthermore, the present invention has another advantage due to the fact that the design of its pipe loops eliminates the need for expensive agitation equipment to mix chemicals with the water.

Claims (1)

A system (1) for purifying contaminated water comprising at least a first subsystem (2), in which a coarse separation of contaminants takes place in the water, the first subsystem (2) of which is connected to at least one second subsystem (3). ), in which precipitation ceramics are supplied to the water, the second subsystem (3) of which is connected to at least a third subsystem (4), in which a sedimentation of pollutants in the water takes place in at least one precipitation pond or in at least one shielded water area characterized by the supply of precipitation chemicals to the polluted water in the second subsystem (3) takes place in at least one tubular reactor (6), the tubular reactor (6) of which comprises at least a first tube loop (12) with at least one section, preferably your sections with at least one form, preferably fl your forms, compulsory to mix water and precipitating chemicals and that the first subsystem (2) and the second subsystem (3) are wholly or partly enclosed, or substantially enclosed, in for fl removable devices which allow the system to be moved from one location to another. Water purification system (1) according to claim 1, characterized in that the pipe loop (12) has at least one section, preferably fl your sections, with at least one shape which is substantially curved or has another curved shape suitable for the purpose of mixing water and precipitating chemicals. . System (l) for purification of water in accordance with one of the preceding claims, characterized in that the units which can be exchanged consist of containers. System (1) for purification of water according to at least one of the preceding claims, characterized in that the pipe loop (12) has at least one section with a curved shape which is U-shaped. System (1) for purification of water according to claim 4, characterized in that the pipe loop (12) has fl sections of curved shape which are U-shaped. System (1) for purification of water in accordance with at least one of the preceding claims, characterized in that the coarse separation of contaminants takes place via at least one grid, net, screen or the like. 535 438 10 7. System (1) for purification of water according to at least one of the preceding claims, characterized in that the subsystem for sedimentation takes place in a water area shielded by screen walls in a lake, sea, watercourse or the like whose sensed area comprises at least one partition . System (1) for purification of water according to claim 7, characterized in that the protected water area is separated via at least one screen wall which at its lower end is connected to the lake bottom and at its other end extends above the water surface.