CS240183B1 - Method of drinking-water final treatment and agent for its performance - Google Patents

Description

(54)

Method of finishing the treatment of drinking water and means for its implementation

Both the method and the composition are intended for the final treatment of drinking water directly at the consumer. The water first comes into contact with the oligodynamically acting metal, then with the ion exchanger and then passes through the filter element. As it passes through the filter cartridge, the water comes into contact with sorption agents, in particular activated carbon. The filter and sorbent composition consists of two stages, the first stage comprising at least 20% ion exchanger and the second stage consisting of a filter element, the carrier part of which consists of synthetic fibers containing 20 to 70% powdered activated carbon bonded to the surface of the synthetic fibers with polyacrylate binder.

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The present invention relates to a process for the finishing of drinking water in the water system by passing through a filter means and contact with a sorbent and a filter and sorbent for carrying out the process.

Drinking water from an underground or surface source contains foreign substances physiologically adversely affecting the human organism. These substances, which are generally a product of the blue environment, are mainly carried out in waterworks, where the content of foreign substances is reduced to the limit specified by the standard. However, the drinking water thus prepared often still contains a proportion of foreign substances which is undesirable from a medical point of view and, for example, completely inadmissible for infants or young children. Longer central cleaning would require very complex technological processes and correspondingly costly equipment. This procedure would also be ineffective because it would. Direct personal consumption consumes only a small part of the drinking water.

For these reasons, methods and devices have been developed for the final treatment of drinking water directly at the consumer. Alluvial filtration, microfiltration filtration, ion exchange resins, granular activated carbon, powdered activated carbon and other sorption materials are used.

The known solutions for the final treatment of drinking water remove partly or almost completely foreign substances from the treated drinking water, but at the same time the physiologically important and essential for the human organism is eliminated. In addition, the microbiological and biological properties of the treated waters deteriorate. For granular activated carbon filters, the sorption capacity of activated carbon is not sufficiently utilized.

240 183 resulting in rapid wear of the cartridge and frequent replacement. When powdered activated carbon is used, the sorption effect is considerably higher. However, filters employing a pulverized carbon passage require a structurally demanding design to prevent undesirable penetration of pulverized activated carbon into the treated water, thereby also returning undesirable foreign matter to the water.

For example, in one known method, the treated water is passed through a paper, fabric or nonwoven bag filled with activated carbon or ion exchange material. The aforementioned general disadvantage of this method is that they do not utilize the active areas of activated carbon because the water flows erratically through the bag.

According to another known method, the treated water passes through a filter fabric wrapped around a perforated tube in which the water distribution baffles are provided. The general disadvantages here are the low use of filter fabric, since water passes through the fabric substantially in streams corresponding to the holes in the perforated tube.

It is an object of the present invention to provide a reliable and simple method of finishing drinking water treatment, including appropriate filtering and sorption means, to overcome the shortcomings of the prior art, enabling the drinking water treatment to be completed by the consumer.

The principle of the process according to the invention is that the water first comes into contact with the oligodynamically acting metal, then with the ion exchanger and subsequently passes through the filter element, where it comes into contact with the sorption means, in particular with the active powder coating.

The principle of the filtering and sorption agent according to the invention is that it consists of two stages, the first stage comprising at least 20% ion exchangers and the second stage consisting of a filter element, the carrier of which consists of synthetic fibers containing 20 to 7θ $ powdered activated carbon on the surface of synthetic fibers with a polyacrylate binder.

For the sake of simplicity, it is preferred that the first stage consists of an ion exchanger in granular form or consists of

240 183 a filter element, the carrier of which consists of synthetic fibers, comprising a 20 to 70 - anion exchange powder or cation exchange resin which is bound to the surface of the synthetic fibers by a polyacrylate binder.

For production reasons, it is preferred that the first. .i second stage. has the form of a rolled comb.

The main advantage of the invention is the simplicity of implementation while achieving relatively very good effects in the removal of physiologically harmful substances without the risk of the release of powdered sorbents into the drinking water.

Examples of apparatuses including filtration and sorption means for carrying out the process according to the invention are shown in the drawings, in which Fig. 1 shows an apparatus where the two stages of filtering and sorbent are arranged on top of each other and Fig. 2, where both stages of refining. and the sorbent are arranged side by side.

According to. example. In an embodiment, the apparatus is connected to the outlet of the water supply system by means of a bath battery which comprises a two-way valve 2 for supplying contaminated water to the apparatus or directly to an outlet for a purpose other than immediate personal consumption. In the housing 3 of the device (Figs. 1, 2). a perforated tube 4 is provided, at the end of which a pressure plate is attached. The body 3 is closed by a lid 6 through which the perforated tube 4 passes and changes into the drinking water outlet 2 at the point of passage. Said device may also be integrated in the water supply system for further water treatment for the whole object, for example a hospital, school or the like. Then, the inlet and outlet of the device are appropriately adapted for connection to the water supply piping.

The inside of the body 8 forms a filter chamber 8, and a sorption agent is arranged in the filter chamber 8, according to an exemplary embodiment of the filter element 2. It consists of two stages, the second stage 11 being mounted on the perforated tube 4 and surrounded by the first stage 10 (FIG. 1). The two stages 10, 11 are clamped between their ends

They are coaxial and concentric to each other in that the first stage 10 is wound on the second stage 11 '. steps 10, 11 are in the form of a rolled comb ·

According to another embodiment, the two stages of the filter element 6 are arranged directly on the perforated pipe 4. The first stage 12 is located closer to the inlet of contaminated water, the second stage 13 is located closer to the outlet of the purified drinking water (Fig. 2). j® separated from the second stage lj by a circular partition 14 which also extends through the perforated tube 4 '

According to both exemplary embodiments, an oligodynamically acting metallic material, such as copper, silver or alloys of these metals, is placed in the filter chamber 8. For example, the pressure plate D is made of an oligodynamic material or the whole body is made of this material, or the body 6 is coated with an oligodynamically acting metal (FIG. 1). Another example is the embodiment of the perforated tube 4 or at least its initial part of the oligodynamically acting metal.

The first stage 10 comprises at least 20% of an ion exchanger which is a strongly basic anion exchanger, for example the trade name Wofatit Y 53, or a cation exchanger, for example of the Ostion KS type. In the present case, the first stage 10 thus comprises practically 100% ion exchanger.

Preferably, the first stage 10 comprises a nonwoven bonded web, the backing of which is synthetic fibers. On the surface of these synthetic fibers, an anion exchange resin or cation exchanger is bonded with a polyacrylate binder, namely 20 to 70% of the total weight of the first stage 10. The individual ion exchanger particles have a particle size of up to 100 µm.

The second stage 11 consists of a nonwoven bonded fabric, the backing of which is formed of synthetic fibers. Powdered activated carbon with a particle size of up to 100 µm is bonded to the surface of the synthetic fibers with a polyacrylate binder. The weight of powdered activated carbon is 20 to 70% of the total weight of the second stage.

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All examples of the first stage 10 and the second stage 11 can be applied both to the regulation of FIG. 1 and to the apparatus of FIG.

The method of finishing the drinking water treatment according to the invention and the function of the device proceed as follows:

Contaminated water is introduced into the filter chamber 8 where it first comes into contact with the oligodynamically acting metal, thereby ensuring the microbiological safety of the drinking water.

In a further stage, the water passes through the first stage 10 or 12 of the filter cartridge and comes into contact with the ion exchanger. Finally, the water comes into contact with activated charcoal as it passes through the second stage 11 or 13 of the filter cartridge, thereby removing physiologically harmful substances, released oligodynaraic metal ions, unpleasant odors, flavors and free chlorine.

Claims (6)

SUBJECT IN A G U A L S Z U I · 240 183 1. A method of finishing drinking water in a water supply system by passing a filter means and contacting a sorbent, characterized in that the water first comes into contact with an igigodynamically acting metal, then with an ion exchanger and subsequently passes through a filter element where it comes into contact with the sorbent. compositions, in particular activated carbon. 2. The filtering and sorption means for carrying out the process according to claim 1, characterized in that it comprises two stages (10, 11 or 12, 13), the first stage (10 or 12) comprising 20 to 70% ion exchange resin and the second stage (10). 11 or 13) is formed by a filter element, the backing of which consists of synthetic fibers containing 20 to 70% powdered activated carbon bonded to the surface of the synthetic fibers with polyacrylate. connective. 3. The filtering and sorption agent according to claim 2, wherein the ion exchanger is in granular form. 4. The filtering and sorbent composition of claim 2, wherein the first stage (10 or 12) has a carrier portion of at least one fiber type selected from the group consisting of polyester, polyamide, polypropylene and viscose fibers and contains 20 to 70% anion exchange powder. which is bound to the surface of the synthetic fibers by a polyacrylate binder. 5. The filtering and sorbent composition of claim 2, wherein the first stage (10 or 12) has a carrier portion of at least one fiber type selected from the group consisting of polyester, polyamide, polypropylene, and viscose fibers and comprises from 20 to 12 fibers. 70% powdered cation exchanger, which is bound on the surface of synthetic fibers by polyacrylate binder. 6. The filtering and sorption means according to any one of claims 2 to 5, characterized in that the first stage (10 or 12) and the second stage (11 or 13) are in the form of a cylindrical winding.