DE8815345U1 - Water purifier - Google Patents

Description

Munich, 26.6.1989

OSBERMA

Wiehlpuhl

5250 Engelskirchen

Description

Water purifier

The present invention relates to a water purifier, as it is generally used in the home, in the laboratory and for hobby purposes. The invention relates in particular to a water purifier for the treatment of pollutant-free drinking water and process water for dialysis centers, which has a high degree of purity, as well as process water for a wide variety of needs, eg fully demineralized and germ-free water, or ¹ also concentrated

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There are already known processing devices for seawater desalination that are equipped with plate modules that work according to the principle of reverse osmosis. Such plate modules are known from the German patents DE-PS 23 53 659, DE-PS 24 46 157 and DE-PS 25 56 210. The principle of reverse osmosis is described schematically as follows. In natural osmosis, between two solutions of different concentrations that are separated by a semi-permeable membrane, the solvent migrates through the membrane into the more concentrated solution. This is called osmosis. The solvent transport through the membrane continues until the hydrostatic pressure difference S P is equal to the osmotic pressure ρ of the solution. If a pressure is now exerted on the more concentrated solution that is higher than the osmotic pressure ρ , the flow direction is reversed and the solvent in the more concentrated solution migrates into the less concentrated solution. In this way, a separation takes place and on the one hand you get a permeate that is free of undesirable ingredients and on the other hand a concentrate that contains these ingredients in concentrated form.

These undesirable ingredients include nitrates, sulfates and other salts that are formed due to the

A major problem with all desalination devices available on the market is their adaptation to changing water consumption. Depending on the quality of the raw water, when the device is switched off, the filtering devices become contaminated by deposits. It is therefore common practice to run such devices, especially larger systems, in continuous operation. If the demand for permeate stagnates, the permeate line is simply shut off and the permeate flows through the

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increasing environmental pollution in the water* Heavy metals such as lead, barium, cadmium and mercury have been detected in increased concentrations in drinking water. Finally, organic impurities, as well as bacteria and viruses, are a problem* There are also particulate suspended matter and disperse phases, which are also undesirable* The well-known plate module can reduce, if not eliminate, all of these ingredients. Such plate modules also have the advantage that they do not require water retention measures and chemical cleaning, which are always required for other desalination devices. Instead of the permeate, the concentrate of a solution can also be used, for example to reduce the volume of undesirable liquid substances or to remove valuable liquids.

Concentration* Such a process is not satisfactory because it results in a very high and unnecessary consumption of raw water and the devices are exposed to unnecessary wear*

The object of the present invention is to create a water treatment system that ensures minimal liquid consumption and can be flexibly adapted to changing permeate or concentrate requirements.

The problem is solved by a water purifier with a supply line, a plate module operating according to reverse osmosis, a concentrate line and a permeate line which is connected to a container for collecting the permeate _; &uacgr;&*~ is characterized by turbulence elements installed in the plate module, a shut-off device arranged in the supply line and a level sensor installed in the container which is connected to the shut-off device.

With the water treatment device according to the invention, it is possible to control the liquid supply according to the current liquid requirement. The shut-off device can be controlled depending on the fill level measured in the container. The

Turbulence elements ensure that the water flow in the channels is swirled. On the one hand, they prevent laminar flow during continuous operation of the plate module, which is a danger to the fine-pored membranes. With laminar flow, ingredients can easily sediment and clog the membranes. On the other hand, the turbulence elements ensure that when the module is switched off and the deposits are switched on again, they are quickly dissolved and flushed out. The water purifier guarantees that the plate module will continue to operate properly, even after it has been shut off or switched off by the shut-off device. The water purifier is particularly suitable for use in the treatment of drinking water in households and works satisfactorily with the ^network available there. It is also suitable for use in laboratories, dialysis centers and for tasks involving the concentration of liquids.

The level sensor used preferably has a float that is coupled to a float valve as a shut-off device. This means that the sensor and the valve are independent of electrical current and both parts can be designed inexpensively. In another embodiment, the shut-off device can be an electric valve that responds to the float state.

reacts. The solenoid valve can be designed either as a control valve with continuous flow or as a switching valve with two states.

The supply line is preferably connected to a water connection as available in the water network, while the concentrate line is connected to a waste water connection I. This allows for convenient installation in the

Household possible. The concentrate does not contain any f

Ingredients that are not present in the water network and therefore does not lead to any additional contamination of the wastewater network. A check valve can be installed in the concentrate line to control the concentrate discharge. ■

This valve is used to set the required operating pressure in the system. The pre-pressure is generated either by the normal water network pressure or by a pump installed upstream of the module, while the system pressure is set by the check valve.

A pump and a discharge line for water extraction are preferably provided on the water tank, with which the water can be directed to any location, e.g. in the household. A pressure pump is provided between the shut-off device and the plate module. If the net pressure is too low or ^the salt content is so high that the? I

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This situation can be found, for example, in water-scarce regions. The pressure pump ensures sufficient wastewater pressure under such difficult conditions.

In the case of problematic raw water, which, for example, has extreme amounts of hardness-forming substances or extreme amounts of chlorine, a slight pre-treatment of the raw water, e.g. in the form of activated carbon filtration, addition of harmless treatment promoters or the like, is preferred. The activated carbon filter is preferably provided between the water connection and the shut-off device. This filter ensures dechlorination and deozonation, as well as the reduction of BOD, COD and TOC. The absorption of odors, flavors and colors is also provided. In addition to the activated carbon filter, a fine dosage of treatment promoters is also provided. Such promoters are, for example, anti-scaling agents, which prevent the deposit of hardness-forming substances or "blocking". The anti-scaling agent is separated by reverse osmosis and excreted together with the concentrate.

It is preferable to also provide a shut-off device in the permeate line or concentrate line, which is directly coupled to the shut-off device in the supply line. This enables a simple and cost-effective design of the control system. In particular

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the shut-off device in the permeate line or concentrate line can be operated manually and a proportional actuation signal can be transmitted to the shut-off device in the supply line.

Further advantages, features and possible applications of the present invention emerge from the following description of several embodiments in conjunction with the drawing.

Fig. 1 shows the function of a plate module operating according to reverse osmosis;

Fig. 2 shows an embodiment of the water purifier according to the invention with float valve, retaining valve and permeate container;

Fig. 3 shows a further embodiment of the water purifier according to the invention with container, electric valve and pressure pump;

Fig. 4 shows an embodiment according to the invention with an additional shut-off device in the permeate line;

Fig. 5 shows an embodiment of the invention in which the shut-off device is controlled by a manual shut-off device in the permeate line;

Fig. 6 shows an embodiment according to the invention corresponding to Fig. 2, in which the concentrate

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Fig. 7 shows an embodiment in which a manual shut-off device is provided in the concentrate line;

Fig. 8 shows an embodiment with pressure switch element in the supply line; and

Fig. 9 shows an activated carbon filter and a device for fine dosing of treatment promoters.

Fig. 1 shows the plate-like structure of the plate module, which works according to reverse osmosis. At a the feed line is connected, at b the permeate line and at c the concentrate line. Conventional turbulence elements are used.

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Due to the nature of the module, the connections can also be reversed without changing the module. For example, c can be the raw water connection, while via a [ is the concentrate discharge and via b is the permeate discharge \

It is possible to change the flat ] Membranes in the plate module, e.g. for low or high salt retention rates or for ultra-filtration. -

Figures 2 and 3 each show a sketch of an embodiment of the arrangement according to the invention. The i

Embodiments have a city water connection 1 and | a waste water line 2. The city water supply is branched off from a conventional water pipe. Instead of | city water, any other water, e.g. brackish water, problem water or the like, can be used.

Problem waters are, for example, landfill leachate, liquid manure, etc. In the embodiment according to Figure 2 , a float valve 3 is shown in the supply line, which reacts to the filling level of a water tank 6, which is sensed by means of a float. In the other embodiment according to Figure 3, a float valve 3 is also shown. a float is provided, but instead of the float valve an electric valve 10 is used, which reacts to the float rod with an on/off signal. The supply line a goes into the plate module 4, where a reduction or filtering of the ingredients | takes place. In the second embodiment an additional pressure pump 9 is shown, which compensates for insufficient network pressure * or too high a salt content. A permeate line C b leads into the water tank 6, in which a pump 8 with discharge line 7 is arranged. Via the discharge line 7 _s

The drinking water is extracted and fed into a !

collecting container 11. In the concentrate line, a retaining valve 5 is shown, which is used to regulate the amount of

concentrate discharge. The concentrate line is connected to the f

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In the first embodiment, only the water tank pump 8 needs to be provided with a power supply. All other parts work without electricity. In the second embodiment according to Figure 3, the pump 8, the electrovalve 10 and the pressure pump 9 need to be connected to a power supply. The additional power requirement for the electrovalve is low, since it only switches when necessary .

In the embodiment according to Figure 4, an additional blocking device 12 is provided in the permeate line b, which connects via a coupling line 13 to the general shut-off device 14 arranged in the supply line a. The shut-off device can be coupled mechanically, electrically or hydraulically. Manual actuation of the shut-off device is also provided. The coupling line transmits a coupling signal which is proportional to the blocking signal at the blocking device 12 and causes a proportional blocking signal at the shut-off device 14. The shut-off device works mechanically, electrically or hydraulically. When permeate is required, the shut-off device 14 is only opened by actuating the control device 12, so that the arrangement is switched on.

Figure 5 shows an embodiment in which a manual locking device 15 is arranged in the permeate line b, which is connected to a shut-off device 14. In contrast to other embodiments, here a direct permeate

Collection via line 7 without collection tank. 30

Figure 6 shows an embodiment in which the concentrate from the concentrate line c represents the desired product, while the permeate is discharged in the permeate line b . Otherwise, this embodiment corresponds to that of Figure 2.

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In Fig. 7, an embodiment is shown in which a manual blocking device 15 is arranged in the concentrate line c, which connects via a coupling line 13 to a general shut-off device 14 in the permeate line a. This embodiment is advantageous when the system pressure set by the manual blocking device 15 has to be adjusted, or the concentrate can only be released into the sewage system at certain times.

Figure 8 shows an embodiment in which the concentrate from the concentrate line c represents the desired product. A pressure switch element 16 is arranged in the supply line a, which shuts off the mains water flow if the mains water pressure is insufficient so that no unnecessary mains water is consumed. The pressure switch can also provide dry-run protection for a downstream pressure pump.

Figure 9 shows an activated carbon filter 17' and a device 18 for fine dosing of processing engines. The activated carbon filter unit 17 is connected upstream of the plate module. Behind the activated carbon filter unit 17 is a

Fine dosing 18 intended for anti-scaling agents. 25

The performance of the plate module depends on the number of flat membranes with which it is equipped. Instead of one module, several modules can be connected in parallel to increase the performance. A series connection of the plate modules

is recommended when only a limited cleaning can be achieved in one pass, especially when concentrating.

Claims (9)

Munich, 26*6.1989 OSBERMA (New) Protection Claims 1. Water treatment device, with a supply line (a), a plate module (4) operating according to reverse osmosis, a concentrate line (c), and a permeate line (b) which is provided with a container (6) for collecting the permeate, characterized by turbulence elements installed in the plate module, a shut-off device (3) arranged in the supply line (a), and a level sensor installed in the container, which is connected to the shut-off device (3). 2. Water treatment device according to claim 1, characterized in that the level sensor is a float and the shut-off device is a float valve. 3. Water treatment device according to claim 1 or 2, >* ·*■ tu i: . '·■'\&Lgr; characterized in that the supply line is connected to a water connection (1), and the concentrate line is connected to a waste water connection (2). 4. Water treatment device according to one of the preceding claims, characterized in that a retaining valve (5) for controlling the system pressure is arranged in the concentrate line (c). 5. Water treatment device according to claim 1, characterized in that a pump (8) and a discharge line (7) for the removal of the permeate are provided on the container (6). 6. Water treatment device according to one of the preceding claims, characterized in that a pressure pump (9) is provided between the shut-off device and the plate module. 7. Water treatment device according to one of the preceding claims, characterized in that an activated carbon filter (17) is inserted between the water connection (1) and the shut-off device (3). 8. Water treatment device according to one of the preceding claims, characterized in that between the water outlet (1) and the shut-off device (3) a <· Il I KIIIIi(I suffered * I ««Iff &bull; t 4 * » $ &igr; § t Device for fine dosing of processing promoters (18) is provided. 9. Water purifier according to one of the preceding claims, characterized in that a shut-off device (12, 15) is provided in the concentrate line or permeate line, which is connected to the shut-off element (3, 14) in the supply line. 1 I f &igr; * &igr; * t .N r ( &igr; fti &igr; * I * &iacgr;&igr;&igr; I *<«' nt tu ti*