DE3840193A1 - Tubular filter - Google Patents

Abstract

In tubular filters for solid/liquid separation, deposits can occur on the internal surface of the filter tubes (5), as a result of which the filtrate flow can greatly decrease. This makes oversizing and cleaning of the tubes necessary. This cleaning is conventionally carried out at intervals and leads to interruptions in operation and thus to increased production costs. The object underlying the invention is to design a tubular filter in such a way that continuous cleaning and thus continuous operation are possible in order to decrease the capital and production costs. This object is achieved by arranging in the lower chamber (4) of the vertical tubular filter a perforated plate (10) which separates off a space (4b). In this space and in the filter tubes (5) there is a granular mass (11) which is fluidized by the medium to be purified and which keeps the internal surface of the filter tubes (5) free of deposits by the turbulence generated and by mechanical contact. The tubular filter according to the invention is suitable for use in all processes and methods which depend on solid/liquid separation and purification of liquids with the lowest possible costs. <IMAGE>

Description

The invention relates to a tube filter for mechanical separation of solid / liquid mixtures with a container wall and a bundle of parallel, vertical filter tubes that act as permeable membranes trained and in an upper and a lower Tube bottom are attached, being between the top Tube top and container wall with an upper chamber an outlet nozzle for the concentrate and between lower chamber and lower chamber with an inlet connection for the medium to be treated be formed as well as in the cylindrical part of the Container wall slightly above the lower tube sheet a permeate outlet.

Such filters are of various designs used. Depending on the desired separation limit also the membrane filter for the Reverse osmosis, ultrafiltration, microfiltration or the like application. So are the most diverse Known versions, such as winding membranes, Plate membranes, hollow fiber membranes and tubular membranes (DE-OS 28 44 941, DE-OS 28 45 003, DE-PS 29 32 194).

During the concentration it comes through the Transport of solids towards the membrane Deposits on the inner surface of the membrane and as Consequence of this is a reduction in the filtrate flow. Depending on the type and composition of these  Solids and depending on the pore structure of the membrane can the filtrate flow decrease significantly, and ultimately can it even clogged the filter completely come.

Efforts have not been lacking in this To remove membrane contamination prevent it by taking suitable measures. Are known e.g. periodically initiated cleaning procedures with Help with chemical cleaning agents. You also have Processes developed by sporadic Introducing round cleaning bodies, e.g. out Foam rubber, in the process stream cleaning the Filter tube walls mechanically due to frictional contact he follows. Finally, backwashing is known, e.g. from EP 00 21 547, in which the periodically Pressure ratios are reversed, and by the reverse flow direction in the membrane wall itself is removed from the top layer forming the solids.

All known methods are concerned discontinuous cleaning methods. Consequently the devices have to flow to a certain volume to ensure cleaned medium (permeate) because the pollution that occurs always to a certain extent Overcapacity can be designed, leading to increased Investment costs leads. Beyond that such devices through necessary fittings and Additional installations more expensive. Another disadvantage are the business interruptions for the Watch cleaning procedures, which increased Production costs.  

The invention is based on the object To create tube filters of the type mentioned at the beginning, which is a continuous cleaning of the inner surface the filter tubes allowed and at the same time the disadvantages the known filter eliminated.

This object is achieved in that between the lower tube sheet and the inlet nozzle for that too treating medium a perforated plate is arranged that the space between the perforated plate and the lower tube sheet Amount of granular mass that is at least as large is that they are in the operating state of the tube filter together with the medium to be treated, the volume in the filter tubes and between the perforated plate and the lower one Tube bottom fills.

In the case of a tube filter of this construction, the Space between the perforated plate and the lower tube sheet granular mass through the material to be treated Medium fluidized and kept in a state in where the two media come together like a liquid behave in that the individual particles in the Be held in limbo. Part of the granular mass by the upward flowing, too treating medium in the filter tubes in suspension held. The amount of granular mass is at least dimensioned so that it is sufficient to filter the to fill this fluidized state. Already at low throughput is in the to be treated Liquid in the filter tubes due to the movement of the granular mass a turbulent flow state generates a layer formation on the inside of the Filter pipes completely or at least largely prevented. Beginning deposits of solid particles are  immediately by the impact of the individual Particles of the granular mass again mechanically from the Filter tube wall detached. That way is one continuous cleaning of the filter tubes guaranteed and continuous operation of the system without the usual Business interruptions possible. The special advantages of the tube filter according to the invention are the one lower investment costs compared to conventional ones Apparatus, as an interpretation that the through Layering on the membrane caused reduction of the filtrate flow is not taken into account here is required. On the other hand, the fact that no business interruptions for the usual discontinuous cleaning are necessary, too reduced production costs or the same Design as before for an increased output.

Under the designation filter tubes, which are considered permeable Membranes are formed, on the one hand, are discrete To understand pipes whose wall consists of a support or Carrier material exists and in which the inner wall from a permeable membrane, i.e. a layer with much lower porosity than that of the Carrier material exists. On the other hand, there is also to understand a structure in which one Group of such filter tubes in so-called Membrane elements summarized and in Pipe-like, porous molded parts are introduced. This has the advantage of being significantly improved Stability towards individual, discrete tubes.  

In order to avoid that the same particles of the granular mass in the filter tubes can pass through suitable dimensioning of the pipes and through a Enlargement of the granular mass can be ensured that the particles together at the top of the filter tubes with the concentrated liquid, the retentate, emerge. These are then replaced by one or more return pipes arranged between the tube sheets or by other suitable return devices from the upper chamber back into the lower chamber promoted. This way you will be premature Prevention of wear of some of the particles. The Repositioning and simultaneous enlargement the amount of granular mass is also necessary if for procedural reasons the Flow velocity in the filter tubes is high must be chosen.

It is advantageous to manufacture the filter tubes from wear-resistant, inorganic material in order to ensure the longest possible service life of the tube filter. However, these materials are of particular advantage when designing the tubular filter according to claim 2. Depending on the application, ie aggressiveness or abrasiveness of the medium to be treated, the pressure and the temperature, the filter tubes are preferably made of ceramic, in particular Al ₂ O ₃ or ZrO or in Carbon executed.

The material of the granular mass should not be harder, i.e. not more wear-resistant, than the material of the filter tubes in order to avoid premature wear and tear. According to a further development of the invention, it is provided that the granular mass consists of the same material as the filter tubes, such as Al ₂ O ₃ , ZrO or carbon.

Basically come as particles for the granular mass only those in question through their movement and their inevitable contact with the wall of the filter tubes do not destroy them. I.e. the particles must not have sharp edges or corners. To one if possible to achieve a long service life for the filter tubes Particles advantageously formed spherically.

Depending on the aggressiveness of the liquid to be treated and the type of solids contained therein as well Abrasiveness of the material of the filter tubes and the Granular mass can be beneficial or even necessary be the particles partially or entirely during the To be able to replace operation of the tube filter, and either periodically or continuously. Is to the training provided according to claim 7, in which worn particles are withdrawn from the upper chamber and at the same time the corresponding amount of new particles be added to the lower chamber.

An embodiment of the invention is in the Drawing shown and will be described in more detail below described.

The tube filter consists of a container in which an upper tube sheet 1 and a lower tube sheet 2 are inserted, so that an upper chamber 3 and a lower chamber 4 are formed. Filter tubes 5 are inserted into the tube sheets 1 and 2 , in which the medium to be treated flows from the lower chamber 4 into the upper chamber 3 . On the lower chamber 4 there is an inlet connection 6 for introducing the medium to be treated, whereas the upper chamber 3 has a connection 7 for discharging the concentrate (retentate). The solid-free liquid which has passed through the permeable filter tubes 5 , the permeate, is drawn off via a nozzle 8 in the cylindrical part of the container wall 9 . Within the lower chamber 4 , a perforated plate 10 is provided which divides the lower chamber 4 into the rooms 4 a and 4 b . In the operating state, the granular mass 11 is located in the space 4 b above the perforated plate 10 . The medium to be cleaned, ie the liquid loaded with solids, first reaches the space 4 a via the inlet connection 6 , flows through the perforated plate 10 and keeps the granular mass 11 in a fluidized state. Part of the particles is held in suspension by the medium to be cleaned in the filter tubes 5 , where, due to the turbulence they generate and the mechanical contact with the wall of the filter tubes 5 , the latter is prevented from depositing. In the stationary state of this exemplary embodiment, the granular mass 11 extends straight to the upper end of the filter tubes 5 , so that the upper chamber 3 contains practically only concentrate (retentate) which flows off via the nozzle 7 . The cleaned liquid, the permeate, flowing through the filter tubes 5 flows out through the nozzle 8 .

Claims (9)

1. Tube filter for mechanical separation of solid / liquid mixtures with a container wall and a bundle of parallel, vertical filter tubes, which are designed as permeable membranes and are fastened in an upper and a lower tube plate, with an upper chamber with an outlet connection between the upper tube plate and the container wall a lower chamber with an inlet connection for the medium to be treated is formed for the concentrate and between the lower tube sheet and the container wall and a permeate outlet connector in the cylindrical part of the container wall slightly above the lower tube sheet, characterized in that between the lower tube sheet ( 2 ) and the inlet connector ( 6 ) for the medium to be treated, a perforated plate ( 10 ) is arranged so that the space ( 4 b ) between the perforated plate ( 10 ) and the lower tube sheet ( 2 ) contains an amount of granular mass ( 11 ) which is at least so large that they in the operating state of the tube filter together with the medium to be treated, fills the volume in the filter tubes ( 5 ) and between the perforated plate ( 10 ) and the lower tube plate ( 2 ). 2. Tube filter according to claim 1, characterized in that each have a group of as permeable membranes trained filter tubes in membrane elements summarized and in tube-like, porous Moldings are introduced.   3. Tubular filter according to claim 1 or 2, characterized in that one or more return pipes are provided between the two tube sheets ( 1 and 2 ). 4. Tube filter according to one of claims 1 to 3, characterized in that the filter tubes ( 5 ) consist of wear-resistant, inorganic material. 5. Tube filter according to claim 4, characterized in that the filter tubes ( 5 ) consist of ceramic. 6. Tube filter according to claim 4, characterized in that the filter tubes ( 5 ) consist of carbon. 7. Tube filter according to claim 4 or 5, characterized in that the granular mass ( 11 ) consists of the same material as the filter tubes ( 5 ). 8. Tube filter according to one of claims 1 to 7, characterized in that the particles of the granular mass ( 11 ) are spherical. 9. Tube filter according to one of claims 1 to 8, characterized in that on the upper and / or lower chamber ( 3 or 4 ) additional devices are arranged for supplying and removing particles of the granular mass ( 11 ).