WO2006097277A1

WO2006097277A1 - Method for disinfecting drinking water and device for carrying out said method

Info

Publication number: WO2006097277A1
Application number: PCT/EP2006/002327
Authority: WO
Inventors: Hennig Holger; Sandt Burkhard; Joachim Rennau
Original assignee: Aqua Rotter Gmbh
Priority date: 2005-03-14
Filing date: 2006-03-14
Publication date: 2006-09-21
Also published as: DE102005012907A1

Abstract

The invention relates to a method for disinfecting drinking water which is guided through a pipe (1) by adding an aqueous disinfection solution, which contains free chlorine. Said method consists of the following steps: an aqueous sodium chloride solution is prepared in a container (4), a specific amount of the NaCl solution is introduced, in batches, into the electrolysis cell (5) according to the amount of the drinking water guided through the pipe (1), the NaCl solution is electrolysed in the electrolysis cell (5), electrolysis is carried out until the NaCl is at least partially converted into free chlorine, the disinfection solution contained in the electrolysis cell (5) is introduced into the dosing container (9) when electrolysis is completed and the disinfection solution from the dosing container (9) is injected according to the amount of drinking water guided through the pipe(1).

Description

Process for the disinfection of drinking water and apparatus for carrying out the process

The invention relates to a method according to the preamble of claim 1 and an apparatus for performing this method.

The electrolytic production of disinfectant species such as hypochlorous acid, oxygen and minor amounts of hydrogen peroxide and ozone from water itself and native water ingredients has been proven by si-ch for the disinfection of drinking water and drinking water installations. By means of this disinfection method, not only the bacterial numbers of planktonic pathogenic microorganisms (such as legionella, pseudomonads, atypical mycobacteria, etc.) can be reliably reduced by the inactivation and mortality required for a disinfection reduction factor 5 (RF5: reduction of the bacterial count by five orders of magnitude) but also at the front remove any biofilms in the installation system.

Decisive for the disinfecting effect to be achieved is that with the operation of a system for electrolytic disinfection, the required effective concentration of disinfecting substances in the water is generated or introduced into the water and kept constant over the exposure time in permitted limits. In relation to the aforementioned disinfectants, this is representative of the concentration of generated hypochlorous acid (HOCl), measurable as the concentration value "free chlorine", for which the drinking water ordinance specifies the range (0.1 ... 0.3) mg / l. Higher concentrations should be controllably adjustable in order to carry out intermittent "shock disinfection" (so-called "special chlorination").

However, since iris specific care must be taken that the permissible upper limit of the concentration of "free chlorine" is not exceeded, electrolytic disinfection takes place primarily in circulation or supply lines, as shown for example in DE 196 53 696 C2. Since the circulating water has only a certain content of chlorine compounds, a continuous electrolysis can only produce a concentration of "free chlorine" determined thereby.

Sacrificed at stubs an electrolysis is not feasible because when water is drawn, this would flow so quickly through the electrolysis cell so that an effective concentration of "free chlorine" could not ^'be generated. However, the direct addition of disinfectant species into the drinking water causes difficulties, in particular with regard to stocking and precise metering. tion.

It is therefore an object of the present invention, a method for disinfecting led through a pipe drinking water by metered addition of a

indicate "free chlorine" containing aqueous disinfectant solution in which the concentration of "free chlorine" in drinking water can be precisely adjusted, the starting materials to be used are easy to handle and inexpensive to buy, and the "free chlorine" in demand-dependent amount and produced directly at the site becomes.

This object is achieved by a method having the features of claim 1. Advantageous developments of this method and a suitable device for carrying out this method will become apparent from the dependent claims.

Characterized in that an aqueous sodium chloride solution is kept in a reservoir, a certain amount of NaCl solution is added depending on the amount of run through the conduit drinking water in batches in an electrolytic cell, which is electrolysed into the electrolysis cell charge of the NaCl solution, the Electrolysis is carried out until the NaCl is at least partially converted into "free chlorine", after completion of the electrolysis, the present in the electrolytic cell disinfectant solution is placed in a dosing, and the disinfectant solution depending on the amount of guided through the conduit drinking water from the dosing irijiziert into the line, as a starting material only NaCl needed, which is cost-effective and readily available and easy to handle, so that no maintenance personnel for the maintenance is required. The storage tank is sized so that it only has to be replenished at intervals of several weeks. The concentration of the NaCl solution in the storage tank should be as high as possible, whereby it should be ensured that no crystallization problems occur. It should therefore be 70-90%, preferably about 80%. However, since the optimum concentration for the electrolysis is significantly lower, about 15-30%, preferably 20%, the electrolysis cell is filled only to about 1/5 with NaCl solution from the reservoir and then filled with water from the drinking water pipe. The filling of the electrolysis cell can also be such that first a portion of the drinking water, then the NaCl solution and finally drinking water are supplied to the maximum level. A dosing pump controlled by the flow rate in the drinking water line between the dosing tank and the line ensures that a precisely dosed amount of the disinfectant solution is injected into the line as required. An arranged between the metering pump and the drinking water line pressure-maintaining valve is set to a constant pressure, for example, 7 bar. The dosing pump thus always works against a constant pressure, regardless of pressure fluctuations in the drinking water line, so that the amount of the disinfectant solution injected is not influenced by pressure fluctuations in the line.

The invention is described below with reference to one in the

Figure illustrated embodiment explained in more detail. This shows a device for the electrolytic production of a disinfecting solution and their demand-metered addition to drinking water flowing through a branch line. In a designed as a spur line, at the end of at least one tap, formed drinking water line 1, a contact water meter 2 is used, which emits a pulse to an electronic control device 3 after each certain amount of water flowing therethrough. The water flows through the drinking water pipe 1 in the direction indicated by the arrow.

A storage container 4 serves to receive a highly concentrated NaCl solution, which, in order to avoid crystallization, should not exceed a concentration of about 80%. Fill level sensors report to the control device 3 when a minimum fill level has been undershot or a maximum fill level has been exceeded.

A DC electrolysis cell 5 is connected to the reservoir 4 by a pump 6 containing line 7. The electrolytic cell 5 is connected by a line 8 with a metering 9. An inserted into the line 8 solenoid valve 10 is controlled by the control device 3. Furthermore, the electrolysis cell 5 is connected by a line 11 to the drinking water line 1. An inserted into the line 11 pressure reducer 12 sets the pressure in the line 11 on the side facing away from the drinking water pipe 1 side down to about 0.5 bar down. A solenoid valve 13 controlled by the control device 3 opens or closes the line 11 for the supply of drinking water to the electrolytic cell 5. The electrolytic cell '5 and the metering 9 also contain level sensors for detecting a respective minimum level and a maximum level falling below the minimum level and exceeding the limit maximum level each of the control device 3 are reported.

The metering 9 is connected via a line 14 to the drinking water line 1. Into the line 14 are a metering pump 15 controlled by the control device 3 as a function of the quantity of water flowing through the contact water meter 2 and a pressure retaining valve 16 which generates a constant pressure on the side facing away from the drinking water line 1 against which the metering pump 15 must operate. used. This ensures that, regardless of pressure fluctuations in the drinking water pipe 1 at each pump stroke, a defined amount of the disinfecting solution is discharged into the drinking water pipe 1.

The operation of the illustrated device is as follows.

After filling the reservoir 1 with concentrated NaCl solution indicate its level sensors that the maximum level is reached. This is the prerequisite for the automatic operation of the device.

Since the electrolysis cell 5 is empty, report its level sensors of the control device 3, that the minimum level is below. This causes the opening of the solenoid valve 13, so that drinking water flows into the electrolysis cell 5. If a certain level is indicated by a lower level sensor, the solenoid valve 13 is closed again. The control device 3 then causes the switching on of the pump 6 for a fixed duration, whereby a certain amount of the NaCl solution is removed from the storage container. ter 4 is conveyed into the electrolytic cell 5. Subsequently, the control device 3 again opens the solenoid valve 13, so that again drinking water flows into the electrolytic cell 5 until the level sensors indicate that the maximum level has been reached. The incoming water causes a homogeneous mixing of the WaCl solution, which now has a concentration of about 20%.

After closing the solenoid valve 13 begins, although in the metering 9, the undershooting of a minimum level is displayed, the electrolysis process. The NaCl is converted into disinfecting substances using the same term "free chlorine" and consisting primarily of HOCl. Gases produced during the electrolysis are removed via a line 17. The duration of the electrolysis process is fixed. When finished, the resulting disinfectant solution has a free chlorine content of about 1 g / l.

Now, the solenoid valve 10 is opened for a certain duration. After its expiry, the disinfection solution from the electrolytic cell 5 has flowed through the gradient of the line 8 into the metering container 9, as the control device 3 is indicated by the corresponding level sensors. Subsequently, the filling of the electrolysis cell 5 in the manner described above takes place again.

The disinfection of the drinking water can begin now. Whenever water is taken from the tap water line 1 at the tapping points, the contact water meter 2 sends a number of pulses proportional to the amount of water taken to the control device 3 and controls the metering pump 15 such that it executes a corresponding number of pumping strokes. The injected into the drinking water line 1 amount of disinfecting solution is thus proportional to the amount of water removed. By setting the ratio of the number of pulses of the contact water meter 2 to the number of pump strokes of the metering pump 15 in the control device 3, it can be determined how high the concentration of free chlorine at the injection point in the drinking water pipe 1 should be. This can be set, for example, to 0.4 mg / l, if it is ensured that it is degraded to below the first tap to below 0.3 mg / 1 and thus complies with the Drinking Water Ordinance. If a so-called shock disinfection is to be carried out, the aforementioned ratio can also be temporarily changed so that the content of free chlorine at the injection site is increased, for example, 2 to 3 times.

If the fill level falls below a certain value in the dosing tank 9, the control device 3 triggers the electrolysis process. The specific value is selected so that there is still sufficient disinfectant solution in the dosing container 9 to disinfect water taken from the drinking water line 1 until the next batch of disinfectant solution, about 1/2 to 1 hour, is required for this purpose.

If the level of NaCl solution in reservoir 4 falls below the minimum level, then the operator is notified that refilling is required. The minimum time interval between replenishments should be several weeks. If no replenishment occurs after a certain number of additional batches has been dispensed, the total te device off.

The signals of the various level sensors are also used by the control device 3 for the detection of possible errors and for their display and optionally for switching off the entire device.

The electrodes of the electrolytic cell 5 operated with direct current are reversed after each charge, whereby calcification on these is prevented.

Claims

claims

1. A method for the disinfection of guided through a line (1) drinking water by metered addition of a "free chlorine" containing aqueous disinfecting solution, characterized in that an aqueous sodium chloride solution in a reservoir (4) is kept ready, a certain amount of NaCl Solution is given in an electrolytic cell (5) in batches depending on the amount of drinking water passed through the line (1), the charge of the NaCl solution given into the electrolytic cell (5) is electrolyzed, the electrolysis is carried out until the NaCl is at least partially converted into "free chlorine", after completion of the electrolysis in the e- lektrolysezelle (5) located disinfecting solution is placed in a dosing (9) and the disinfecting solution depending on the amount of the guided through the line (1) drinking water from the metering container (9) in the line (1) is injected.

2. The method according to claim 1, characterized in that in the reservoir (4). NaCl solution has a NaCl concentration in the range of 70-90%.

3. The method according to claim 1 or 2, characterized in that the NaCl concentration in the electrolysis cell (5) by supplying water from line (1) is reduced.

4. The method according to claim 3, characterized in that the NaCl concentration in the electrolysis cell (5) is reduced to 15-30%.

5. The method according to claim 3 or 4, characterized in that after the completion of the supply of NaCl solution drinking water from the line (1) is passed to reach a maximum filling level in the electrolysis cell (5).

6. The method according to any one of claims 1 to 5, characterized in that the electrolysis cell (5) is operated with direct current and their electrodes are reversed after each batch.

7. The method according to any one of claims 1 to 6, characterized in that the electrolysis process is triggered upon reaching a minimum filling level in the metering container (9).

8. The method according to any one of claims 1 to 7, characterized in that the electrolysis process is set to a predetermined duration.

9. The method according to any one of claims 1 to 8, characterized in that the disinfecting solution contains 0.6-1.3 g / l of free chlorine.

10. The method according to any one of claims 1 to 9, characterized in that the drinking water the injection site of the disinfectant solution contains at least 0.3 mg / 1 free chlorine.

11. The method according to any one of claims 1 to 10, character- ized in that the concentration of free chlorine in drinking water at the injection site of the disinfecting solution is limited in time to 0.6 to 0.9 mg / 1 is increased.

12. Device for carrying out the method according to one of claims 1 to 11, characterized in that in the line (1) a flow meter (2) is provided for measuring the amount of the guided through the line (1) drinking water.

13. The apparatus according to claim 12, characterized in that between the metering container (9) and the line (1) in dependence on the output signals of the flow meter (2) controlled pump (15) is provided.

14. The apparatus according to claim 13, characterized in that between the pump (15) and the line (1) is set to a constant pressure pressure holding valve (16) is provided.

15. The apparatus according to claim 14, characterized in that the pressure-maintaining valve (16) is set to 6.5-7.5 bar.

16. Device according to one of claims 12- to 15, characterized in that the storage container (4), the electrolytic cell (5) and the Dosierbe- container (9) each at least one level sensor for the detection of a minimum and / or have maximum level.

17. Device according to one of claims 12 to 16, characterized in that between the electrolytic cell (5) and the metering container (9) a to be opened after the completion of an electrolysis process solenoid valve (10) is arranged.

18. A device according to any one of claims 12 to 17, ^■ in that a line containing between the drinking water pipe (1) and the electrolysis cell (5) a solenoid valve (13)

(11) is provided.

19. Device according to one of claims 12 to 18, characterized in that for the batchwise feeding of the NaCl solution, a pump (6) between the reservoir (4) and the electrolysis cell (5) is arranged.