NL1020159C2 - Water purification device with vertical capillary tube membrane module, has two water supply pipes for carrying out purification in opposite directions - Google Patents

Abstract

Water purification can be carried out in the reverse direction by supplying water to the membrane module (2) from a second pipe (15). A device (1) for purifying water comprises top and bottom end caps (16, 17) connected to a vertical capillary tube membrane module via standard couplings (10). The bottom side of the module is connected to a first pipe (11) for supplying water to be purified and the permeate is directed into collectors (3) with a seal (9), from which the permeate is removed from the device via an outlet (13). Water purification can be carried out in the reverse direction by supplying water to the module from a second pipe.

Description

Device for purifying water with the aid of membranes.

When purifying water with the aid of membranes, use has often been made of membrane modules with standard dimensions with a diameter of 8 inches (203.2 mm) and a length of 1, 1.5 or 3 meters. The reason that such membrane modules are used is that they fit in standard standard pressure tubes, they are easily displaceable and in the event of breakage (in the case of the membrane straps in an 8-inch module) not too much capacity is lost.

Membrane modules with larger diameters are also used. A 450 mm diameter module has recently been introduced by Aquasource. This module has a length of 1.30 m and a membrane surface of (1.0 mm straws) 125 m2.

Aquasource has demonstrated that the problem with larger membrane modules does not lie in the difficult handling and integrity of the module. Nor is the problem in the production of such large membrane modules.

Where the problem is is mainly in the water / air distribution with larger diameters. At Aquasource no air / water flushing is applied and therefore this problem does not occur. When scaling up the aforementioned 8 inch module in connection with obtaining a larger capacity of the water treatment plants, it is of great importance that a sufficient cleaning of the module takes place, otherwise there is a good chance that part of the membrane surface will remain permanent becomes contaminated, whereby even the capillaries of the membrane straws can clog up, resulting in a high energy loss and chemical consumption.

The invention now has for its object to provide a device for purifying water, wherein the above-mentioned problem can be solved in an effective manner.

To this end, the invention provides a device for purifying water, wherein the device according to the invention is provided with end caps, respectively on the 1 pO p 2 top and bottom, which are connected by means of standard couplings to a vertically arranged membrane module of the type capillary / tubular, which are connected at the bottom to a water supply tube for the water to be purified, which passes through the membrane module and whereby the permeate ends up in the permeate collectors, which are provided with a seal and leave the device via permeate discharge and leave the concentrate via the discharge line is discharged, wherein in addition the purification can take place in the reverse direction by supplying the water to be purified via the supply line.

The water / air distribution system according to the invention ensures that water and air are optimally distributed over the flow-through surface prior to flushing of the membrane, so that all membrane straws receive substantially the same amount of air and water during flushing of the membrane module.

In order to achieve a good distribution of the water and air, the water supply pipe opens out against the bottom plate, whereby the water is already forced to distribute over the membrane module.

The water supply pipe is provided with a vent pipe at the top to vent the supply pipe.

For an even better distribution of the water, the bottom plate according to the invention is provided with a circular raised edge. An even better distribution of water and air takes place when a distribution plate with openings is arranged between the bottom plate and the bottom of the membrane module, which openings have a diameter equal to or larger than the diameter of the membrane capillaries. It is important here that the hydraulic resistance is at least five times greater than the hydraulic resistance as a result of flowing in / along the membrane straws.

It is also possible to use adapted filter nozzles according to the invention. The use of filter nozzles is known in sand filtration. These classic filter mozzles that

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3 are used in sand filtration, however, are not suitable for raw water because they become clogged as a result of the narrow gap. This problem does not arise with the use of filter nozzles in sand filtration since the filter nozzles in this application are flowed through with clean water (filtrate). When using the usual filter nozzles, the gap width must be adjusted (made larger), allowing flow of dirty water without blockage. It will be clear that the air / water distribution is improved by using filter nozzles.

It has been found to be favorable if the openings on the distribution plate are provided with flaps, for example with rubber, in order to achieve a good air / water distribution.

In a preferred embodiment according to the invention, a good air / water distribution can be realized when the openings in the distribution plate have a relatively large diameter with respect to the membrane capillaries, for example from 0.2 to 1.5 centimeters, which amounts to 300 3000 openings per m2 of floor area. This solution for distributing water and air is a simple and inexpensive solution. Depending on the type of membrane as a rule with a diameter of 1.5 or 5.2 mm capillary / tubular and the diameter of the module from 200 to 600 mm, overall the number of openings can be maintained as follows. When capillaries with a diameter of 5.2 mm are used with modules with a diameter of 600 mm, there are 200 to 400 openings with a diameter of 0.8 cm in the distribution plate. When using capillary membranes with a diameter of 1.5 to 30 mm and a module with a diameter of 600 mm, one can use 200 to 400 openings with a diameter of 0.5 cm. The device according to the present invention comprises a plurality of vertically arranged membrane modules, which contain a plurality of central permeate collectors per module. Depending on the membrane surface per module, so depending on the diameter, 1 or more permeate collectors can be used per module.

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It is noted that the membrane module according to the invention can be of the microfiltration type, ultrafiltration, nanofiltration or hyperfiltration.

The membranes can be capillary or tubular with a diameter of 1-15 mm.

The water / air distribution system according to the invention is particularly suitable for tubular membranes, wherein air and water are simultaneously flushed along to hydraulically clean the membrane surface.

Such a distribution system has been found to be indispensable for scaling up membrane elements from 200 mm diameter to 400 mm diameter or larger.

Such a scaling-up of membrane modules provides advantages in the sense of lower investment costs, in that the membranes become cheaper as a result of an efficient production process, in which fewer elements are required and therefore fewer connections, fewer pipes, and moreover a smaller building volume. Depending on the scale of the installation, construction costs can be considerably reduced, for example 10-20%.

Moreover, a better water / air distribution leads to less contamination of the membranes, so that a higher yield can be achieved with lower energy / chemical consumption.

The invention will now be further elucidated with reference to the accompanying drawing.

This drawing represents a preferred embodiment of the device.

The components are indicated as follows in the drawing: 1. device 2. membrane module 3. permeate collectors 35 4. distribution plate with holes 5. end of water supply pipe (11) 6. vent pipe 7. bottom plate bottom end cap 5 8. raised edge on the inside of the bottom plate 9. sealing of the permeate collectors (3) 10. standard coupling 5 11. water supply pipe 12. gas supply in the supply line 13. separate discharge of permeate collectors (3) 14. concentrate discharge line 15. supply line supply membrane module 10 16. end cap on top 17 bottom end cap

According to the invention, the device (1) for purifying water is provided with vertically arranged membrane module (2), which membrane module usually has a diameter of approximately 600 mm. and a length of 3 m, in which there are 5.2 mm. membrane tubulars.

The membrane module (2) is accommodated in the device between end caps (16, 17) respectively at the top and bottom, which are connected to the vertically arranged membrane module (2) by means of standard couplings (10).

The membrane module (2) is connected to a water supply pipe (11) for the water to be purified.

The water flows through the membrane module (2) in the upward direction, the permeate ending up in the permeate collectors (3), which are provided with a seal (9).

The permeate leaves the device (1) via the permeate discharge (13), while the concentrate formed in this purification process leaves the device via discharge line (14).

It is noted that the purification can also take place in the reverse direction in the device (1) according to the invention, wherein the water to be purified is supplied via supply line 35 (15) and end cap (16) to the membrane module (2), the formed permeate and concentrate leave the device (1) via permeate discharge (13) and concentrate discharge (14) respectively.

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For better operation of the device, it is equipped with a water / air distribution plate (4) which is provided with openings, which water / air distribution plate (4) is received in the end cap (17) between the water supply pipe (11) and the membrane module (2).

It is favorable for the water supply pipe (11) to open against the bottom plate (7), whereby a better distribution of the water to be supplied takes place.

It is also favorable if the inside of the bottom plate (7) is provided with a circular, upright edge (8), which generally has a height of approximately 10 mm.

In a favorable embodiment, the distribution plate (4) comprises approximately 300 holes with a diameter of 8 mm.

It is advantageous if the diameter of the permeate col lectors (3) in the membrane module (2) is approximately 40 mm. is.

It is noted that the permeate collectors (3) are perforated between the membrane tubules, but they are tight in the passage through the upper and lower end caps (16, 17), so that the concentrate and feed cannot flow back into the permeate collectors (3).

With the "forward flush", the released concentrate is discharged via the concentrate outlet (14).

It is furthermore advantageous if a vent pipe (6) is provided on the water supply pipe (11) for venting the feed, which vent pipe (6) usually has a diameter of 5 mm. Gas can be introduced into the water supply line at the location indicated by reference numeral 12.

It is advantageous if the diameter of the openings in the distribution plate (4) is equal to or larger than the diameter of the membrane capillaries / tubulars.

The distribution of the water supplied is further promoted by providing the openings in the distribution plate (4) with flaps or with standard filter nozzles.

The membrane modules (2) are preferably of the microfiltration, ultrafiltration, nanofiltration or hyperfiltration type.

Claims (10)

Device (1) for purifying water, characterized in that the device (1) is provided with end caps (16, 17), respectively, at the top and bottom, which is connected by means of standard coupling (10) to a vertically arranged membrane module (2) of the capillary / tubular type, which is connected at the bottom to a water supply tube (11) for the water to be purified, which passes through the membrane module (2) and wherein the permeate ends up in the permeate collectors (3 ), which are provided with a seal (9) and leave the device (1) via permeate discharge (13), and the concentrate is discharged via the discharge line (14), wherein, moreover, the purification can take place in the reverse direction by purifying it supplying water via the supply line (15). Device according to claim 1, characterized in that a water / air distribution plate (4) with openings is provided at the top of the end cap (17) between the water supply pipe (11) and the membrane module (2). 3. Device as claimed in claim 1 or 2, characterized in that the water supply pipe (11) debouches against the bottom plate (7) via end (5). Device according to claim 3, characterized in that the inside of the bottom plate (7) is provided with a circular, raised edge (8). Device according to claims 1-4, characterized in that a vent pipe (6) is arranged on the upper side of the water supply pipe (11). 6. Device as claimed in any of the foregoing claims 1-5, characterized in that the distribution plate (4) is designed as a flat plate with openings, which have a diameter equal to or larger than the diameter of the membrane capillaries / tubulars. 7. Device as claimed in any of the foregoing claims 1-6, characterized in that the openings are provided with flaps. Device according to one of the preceding claims 1-6, characterized in that the distribution plate (4) is provided with standard filter nozzles. Device according to one of the preceding claims 5 to 8, characterized in that the water supply pipe (11) is provided with a gas supply (12). Device according to any of the preceding claims 1-9, characterized in that the membrane module (2) is of the microfiltration, ultrafiltration, nanofiltration or hyperfiltration type.