FI78666C - Procedure for reducing the iron and manganese content in groundwater - Google Patents

Description

78666

The present invention relates to a method for removing iron and manganese from groundwater, artificial groundwater, i.e. filtered surface water or surface water.

If such water must be purified before use to remove iron and manganese ions, such purification must be carried out in a water treatment plant by adding oxygen to the water. Said oxygen can be added to the water as pure happens or as aerated water, in which case the water is filtered through an aeration cascade. The amount of oxygen required to precipitate ions is relatively small. Once the iron and manganese have precipitated, the water is filtered, for example by filtering it through one or more layers of sand. The capital investment costs of such a treatment plant are high. In addition, the operating costs are very considerable, as the sand layers have to be renewed from time to time to remove precipitated iron and manganese mixtures.

The previous method for treating groundwater is described in SE Publication No. 354,264, in which groundwater is treated on site. Oxygen or oxygen donors are periodically introduced into the aqueous layer from a plurality of syringe wells or nozzles positioned around the intake well some distance therefrom. Oxygen-containing water creates a suitable environment for certain bacteria so that these, together with purely chemical processes, cause the deposition of iron and manganese in the existing base layers, thus acting like a filter. Oxygen-containing water is added periodically and usually over a period of 24 hours. During the addition of oxygen-containing water, the intake well cannot be used to measure water supply to consumers, experimentally this would lead to failures or disturbances in the operating system and deteriorated quality of the treated water, as will be explained later. Thus, two or more intake wells are required to allow continuous water distribution.

The object of the present invention is to eliminate said drawback and to allow water to be pumped continuously from the intake well. The method according to the invention also allows the purification of groundwater or surface water to proceed continuously to the basin or to a filter containing a naturally occurring filter medium.

Thus, the present invention relates to a method for reducing iron and manganese content in groundwater, artificial groundwater, i.e. filtered surface water or surface water flowing through an aqueous bed or a filter containing a naturally occurring filter medium, in which water or oxygen-donating water is intermittently sprayed several times. placed around one or more intake wells or intake pipes for purified water. This method is characterized in that each time water containing oxygen or oxygen donors is introduced, said water is fed to only a few spray wells or jets and water is simultaneously flown from nearby, adjacent or adjacent spray wells or jets to create a zone for oxidizing and precipitating iron and manganese. or at a distance far enough from the ejector tube.

The water supplied to some spray wells may comprise part of the water raised from the intake well and / or water from other nearby spray wells.

3 78666

An embodiment of the invention, namely the treatment of groundwater in an aqueous layer, will now be described in more detail with reference to the accompanying drawing, in which Figure 1 schematically shows a plant for purifying water in an aqueous layer, Figure 2 illustrates runways of added oxygen-containing water if said water is fed into all wells and Figure 3 illustrates oxygen-containing water runways when added in the course of working in accordance with the present invention.

Numbers 1-9 in Figure 1 denote syringe wells, number 10 denotes an intake well, numeral 11 denotes an oxygen station, and numeral 12 denotes a distribution station.

According to a previously known method, water has been distributed from the intake well for, for example, nine days and then the intake well has been inoperative for, for example, one day. On that tenth day, oxygen-containing water has been introduced into all the wells.

In contrast, according to the invention, water containing oxygen or oxygen-donating substances is fed, for example, to a few spray wells, for example wells 1, 4 and 7, over a period of one day (in this case the amount of water added is at least 1/3 of At the same time, water is supplied from one or more other spray wells. During the next day, oxygen-containing water is fed to wells 2, 5 and Θ, for example, and the following day unilaterally water is fed to wells 3, 6 and 9. this water can be oxidized in a conventional manner and used as feed water for spray wells. For several consecutive days, for example seven days, no water is fed to the spray wells and then the cycle is started again (in this example on the eleventh day). Thus, water can be continuously drained from the intake well and only one well is needed to obtain a continuous water supply of the desired quality.

The above information is given by way of example only; other combinations of spray well water volumes and time periods are equally possible. In addition, it is not necessary to place the syringe bars symmetrically around the intake well. Various arrangements are conceivable and determined by local geohydrological conditions.

Figure 2 shows what happens if oxygen-containing water is led to the wells and water is pumped simultaneously from the intake well, but no water is pumped from one or more of the wells. The added oxygen-containing water flows in narrow zones from the respective injection nozzles directly to the intake well. This means that the sprayed water does not cover the entire area between the spray wells and the impure water flows between said narrow zones directly towards the intake well. As a result, a significant portion of the precipitation occurs very close to the intake well. The strainers of the intake well are then clogged and at the same time reduce the efficiency of said well. The intake well may need to be rehabilitated and eventually shut down completely. In addition, the purification method does not work satisfactorily, but leads to a deterioration in water quality.

Figure 3 shows the method according to the invention using, as an example, the introduction of oxygen-containing water into the spray wells 2 and 9 and the withdrawal of water from the spray well 1 (equally well from the extraction well 10). It can be seen that the oxygen-containing water thus derived flows into the aqueous layer in such a way that the areas between the spray wells are completely covered and form a uniform "curtain-type" oxidation and precipitation zone, at a distance sufficiently far from the intake well. This facilitates the continuous flow of purified water from the intake well for distribution to consumers. Some or all of the water flowing from one of the spray wells can be oxidized in a conventional manner and then fed to the spray boilers through which the oxygen-containing water must be led to the aqueous layer.

If the intake well is very deep, then the cost of the spray wells becomes very high and for this reason the normal method using spray wells may be too expensive. Many aqueous layers have several layers containing water, namely layers separated by impermeable or semi-permeable layers. In such cases, the water in the deep intake well can be pumped up from the lower water-containing layers and then fed to filtration wells so deep that the water continues to flow to the higher water-containing layer, where the purification method of the invention can then be performed.

The method according to the invention can also be used for the purification of groundwater or surface water, for example in a basin or in a filter containing naturally occurring filter media. For example, soil can be removed to form a cavity, and a barrier layer formed of clay, concrete, plastic cover, or the like can be placed along the outer surface. Filter or drying pipes for raw water are placed inside the outside of the basin thus prepared, after which the basin is filled with a filter medium, for example sand. Purified water is drained from an inlet pipe or intake well in the center, and syringe tubes are placed between the outside and the center to conduct oxygen-containing water. Instead of such a basin, a filter tank made of steel or plastic or other material can be used. The raw water is led to the inside of the outside of such a filter tank and the purified water is drained from a central inlet pipe. Syringe tubes for oxygen-containing water are placed between the outside and the center. The devices described above will have a radial flow of raw water from the perimeter towards the center of the basin or filter tank, but it is also possible to arrange flow paths in the opposite direction, te. from the center to the outside. Alternatively, the raw water flow may be axial. Thus, the raw water can be fed to one end of the filter tank and the purified water flows back from the other end. In this case, the syringe tubes for the oxygen-containing water are placed in suitable positions between the inlet end and the outlet end.

Claims (3)

78666 A method for reducing the iron and manganese content in groundwater, artificial groundwater, i.e. filtered surface water or surface water flowing through an aqueous bed or a pool or a filter containing a naturally occurring filter medium, comprising passing water or oxygen-donating water around one or more inlets or pipes for purified water, characterized in that each time water is passed through oxygen or oxygen-donating from injection wells or injection tubes to create a zone for acidification and precipitation of iron and manganese, at a distance sufficiently distant from the intake well or intake tube. A method according to claim 1, characterized in that the water fed to some spray wells or spray pipes contains, in whole or in part, water flowing from the intake well or intake pipe. A method according to claim 1, characterized in that the water fed to some syringe wells or syringe tubes contains completely or partially water flowing from other syringe wells or syringe tubes.