DE3127475C2 - - Google Patents

Description

The invention relates to a separation device for fluids according to the preamble of the claim.

In a known separation device according to the genus concept of the main claim (DE-GM 70 22 655) Carrier plates made of plastic use the whole area  are covered by membrane blanks. In the area of The outer edges are on the carrier plate to separate the different flow paths and for overall sealing thin sealing ribs are arranged in the flow chambers, which due to the contact pressure in the microporous Press in the membrane structure. The membrane should be in the loading the actual sealing function of the sealing rib take over. In this respect, this type of sealing is un satisfactory than due to manufacturing tolerances ne plane-parallel formation of the plates and you tion ribs allow and the membrane ge must have white strength so that it is a seal at all can take over function. Depending on the application for dialysis, for ultrafiltration, for the reverse Osmosis, depending on the type of fluids to be treated there liquids or gases, need special membranes be selected so that an optimal material separation is possible. It is known for better sealing in addition to the carrier plates, special sealing plates between the individual layers of the carrier plates to be included (DE-AS 22 09 116), whereby the sealing frames flat blanks of a special Are sealing material. The special sealing material must as well as the membrane and the plastic plates  be autoclavable several times, so that not everyone materials for all purposes and for all Purpose of the separation device is suitable. The Carrier plates made of plastic must have a certain thickness have so that they do not ver ver autoclaving pull and the clamping forces of the overall device withstand. The additional necessary sealing frames increase the overall structure of such a packet-shaped Separation device and pose only additional dangers points for the occurrence of leaks. A new one rer prior art (DE-OS 29 30 986) therefore suggests again the seal with in the carrier plates preformed sealing ribs. One becomes problematic such sealing also in the area of the inlets and outlets, which is mostly circular, the entire stack of Bores passing through carrier plates are formed, that pass horizontally into sub-distribution channels.

However, it is already known (US-PS 35 85 131) to provide slot openings in the carrier plates across the entire width of the membrane overflow area go to better distribution in this way to achieve the fluid flows. In this known separation device, the membrane consists of ver weaved hollow fiber membranes that flow crosswise and are flooded vertically. The tissue-like mem bran is to separate the three fluid spaces from the Carrier plates sealed by a plastic adhesive bead. Again, the construction and sealing is from the forth manufacture very complex. Due to the fabric-like structure there is also a risk that the sealing material not properly in the spaces between the tissues  penetrates and the individual hollow fiber membranes on all sides encloses and seals against the carrier plates.

Deviating from the use of stiff Trä gerplatten it is also known to build multi-layer separating elements from a plastic fabric, a bilaterally arranged, fleece-like carrier material and the bilaterally arranged membranes. The individual separating units are sealed by encapsulating the entire outer edge of the separating element with a synthetic resin. The distribution of the fluid flows within the separating element takes place through bores arranged at a distance from one another at the edges, the adjacent bores being alternately connected outside or inside by an arc-shaped sealing device made of synthetic resin to the sealed outer edges (DE-OS 29 20 253 ∆ US Ser.No. 90 69 22). This type of seal is also unreliable, since it essentially depends on the depth of penetration of the synthetic resin in the individual layers of the separating element to control and narrow down precisely.

The state of the art is still on US-PS 41 13 625, DE-OS 29 30 986, GB-PS 3 29 235, US-PS 34 97 423, DE-OS 23 04 644 and DE-OS 22 05 294 referenced from which the various geometric shapes of the separating elements, sealing elements and carrier plates are known.

In view of this prior art, the invention lies hence the task of one of a variety of To create individual separating elements, which despite the large number of individual separating elements from an economic point of view simple and separating the seal in a technically reliable manner allows the flow paths and flow chambers.  

This object is achieved in that the Carrier plates for receiving the sealing elements Open channel grooves in the plate level and in these openings Chungen, which at least in sections communicate and a introduced in the flowable state and contain solidified sealing material.

The idea of the invention, the most diverse execution is possible in three preferred versions examples with reference to the drawing explained. It shows

Fig. 1 is an exploded perspective drawing of the overall separation device with a vertical section through the connected to a block or square single separation elements according to the section line II in Fig. 2,

Fig. 2 is a top view of two superposed identical support plates with membranes, partly as a section of the front and back

Fig. 3 shows a cross section through a stack of interconnected partition elements according to the section line III-III in Fig. 2,

Fig. 4 is a partial section through a support plate with membrane along the line IV-IV in Fig. 2 and

Fig. 5 shows a longitudinal section through a carrier plate with membrane according to the line VV in Fig. 2,

Fig. 6 shows a detail section through a support plate with a support element of fabric,

Fig. 7 is a side view of a modified device overall,

Fig. 8 is a plan view of an optimized flow under piercing African viewpoints modified carrier plate and that on the side of the membrane,

Fig. 8a shows an enlarged detail from Fig. 8,

FIGS. 9 and FIG. 10a is a plan view of the formed of two half-plates closing plate in the region of the main terminals of the separation device according to Fig. 7,

Fig. 9b and Fig. 10b detail sections on this.

The separating device is constructed from identical carrier plates, which, however, are labeled carrier plate 1 and carrier plate 2 for better identification. Referring to FIG. 2, each support plate 1, 2 is substantially rectangular in plan and rectangular cross section. The carrier plates 1, 2 have on all four rectangle sides a plurality of slot openings 7, 8 , which are interrupted only for reasons of stability by connecting webs 16 . These connecting webs 16 can be omitted in the case of smaller versions of the carrier plates. The slot openings 7, 8 each end in the area of the outer edges of the membranes M 1 and M 2 , so that the fluid flow guided in the slot openings 7, 8 c can sweep the membranes M 1 , M 2 flow-favorably over their entire width. The Trä gerplatte 1 is shown from the membrane side and this side labeled 1 TM . The membrane side of the carrier plates 1, 2 has support elements 4 and flow channels 5 . Referring to FIG. 5, this ge are represented by prism-like in cross-section grooves and lands, said grooves the supporting elements 4 form branzuschnitte for Mem the flow channels 5 at its base and the ridges and ribs. The grooves 5 have longitudinally spaced passages 19 to the opposite side of the carrier plate 1 or 2 in question and the passages 19 are on the opposite side to transverse to the Ril len 5 extending gutters 20 , which in the slot openings 8 for the second fluid F 2 ends. The individual membrane blanks are circumferentially sealed at their edge areas 6 in a kind of pan of the carrier plates by welding or gluing. In the area between the diaphragm edges 6 and the slot openings 7 , spacers 17 and gates 18 are provided, on the one hand he possible that the fluid F 1 from the slot openings 7 through the gates 18 via the membrane top side 1 MO in the direction of the opposite Slot openings 7 can flow, but on the other hand also ensure that the support plates lying one on top of the other hold a sufficient level parallel support by the spacers 17 . Likewise, the back of each carrier plate, shown at 2 TR of the carrier plate 2 is essentially plane-parallel, only interrupted by the collecting channels 20 . The backs of the Trägerplat th 1, 2 are supported against each other on a large area.

For separate guidance of the two fluids F 1 and F 2 , each carrier plate has openings 11 at least at two opposite corner points. In the example lying before breakthroughs 11 are provided at all four corners. These mutually opposite breakthroughs 11 are connected by spur channels 13 running in both directions. In the example, these are arranged on both sides of the carrier plates. However, it is sufficient if these branch channels 13 are provided on at least one side, since the stacking of a plurality of carrier plates ensures that a branch channel 13 is arranged continuously between two carrier plates 1, 2 . In addition, the branch channels 13 are distributed over their length Wei tere openings 12 , the superimposed all carrier plates 1, 2 through like a shaft. These openings 11, 12 and the Stichka channels 13 serve to accommodate the sealant to be described in order to seal off the entire outer area and for permanent connection of the stacked carrier plates 1, 2nd

To seal the fluid space for separate guidance of the fluid F 1 with respect to the guidance of the fluid F 2 parallel to the flow channels 5 outside the edge area 6 of the membrane M 1 , a groove 14 is provided on the two opposite sides of the rectangle, wel che with the branch channels 13 and / or the breakthroughs 11, 12 communicate. These two channels 14 are arranged only on that membrane carrier side of the carrier plates 1, 2 , which is marked in Fig. 2 with 1 TM be. On the back of the carrier plates 1, 2 , two corresponding channels 14 'are provided, which, however, run parallel to the collecting channels 20 and communicate with the branch channels 13 and / or the openings 11, 12 , with 14 and 14', 13 and 11, 12th with you device 15 are filled, as described later. This ensures that the permeate emerging on the membrane rear side passes through the passages 19 of the carrier plates 1, 2 and from the collecting channels 20 into the slot openings 8 , but cannot enter the slot openings 7 , which carry the first fluid F 1 . The rear side of the membranes is designated 2 MR for membrane 2 in FIG. 2.

In addition, openings for mounting clamps 10 are provided in the carrier plates 1, 2 , at least in the four corner regions, which initially serve as a guide for the carrier plates 1, 2 to be stacked on one another during assembly.

The provided with the membrane cuts M 1 and M 2 Trä gerplatten 1, 2 are in pairs with the membranes on each other, as indicated in Fig. 3, mounted on the Mon day tensioner 10 and combined into a stack of 10 or 20 carrier plates 1, 2 . With the help of the mounting clamp 10 and pressure, not shown, the stacked carrier plates 1, 2 are firmly pressed together. All non-recessed surfaces of the carrier plates 1, 2 lie on the counter surfaces of the other carrier plates in a plane-parallel manner. In this preassembled state, a sealant 15 made of a flowable synthetic resin, adhesive or a thermoplastic is injected into the openings 11 . The injection can take place, for example, as shown in FIG. 2 in the lower left opening 11 . If the package of support plates 1, 2 is set up so that the diagonal of the two opposite openings 11 is perpendicular, the injected sealant 15 rises in both directions in the branch channels 11 and the channels 14, 14 ' towards the highest Opening 11 and thereby fills the cavities formed by the openings 11 , the branch channels 13 and the grooves 14, 14 ' by displacement of the enclosed air. Since it is in the sealant 15 is a flowable during the processing time but thermally and / or temporally curable plastic, synthetic resin and / or adhesive, after the solidification of the sealing agent 15 takes place a permanent, tight connection of the individual carrier plates 1, 2 with each other , so that after removing the mounting clamp 10 a paketför shaped or cuboid separating device 30 as shown in FIG. 1 is formed, which can be clamped as a block between the two end plates 27 and 28 sealing.

In order to accelerate the filling of the branch channels 13 and the channels 14, 14 ' and to achieve even better interlocking of the carrier plates 1, 2 with one another over the entire circumference, 13 further openings 12 are additionally provided in the region of the branch channels, which according to FIG. 1 absorb the sealant 15 in through columns.

In the simplest embodiment, the stack of stacked carrier plates 1, 2 is closed by the back of such a carrier plate. The outermost membrane cut is protected against mechanical damage by the back of the outer carrier plate.

To accommodate such a unit are provided for sealing connection with the two end plates 27, 28 on these sealing rings 29 .

If the outer support plates receive an additional protection of the membrane blanks, this may for example by an unprofiled plane Ab-circuit plate 3 on each side of the cuboid 30 gen SUC. The end plates 3 have are as in Fig. 1 provided corresponding slot openings 7, 8. The end plates 3 themselves can also be designed as flat seals, ie they have a certain permanently elastic effect and take over the sealing function between the packet-shaped Trennvorrich device 30 and the two end plates 27, 28 , so that no special ring seals 29 are necessary in these.

Referring to FIG. 1, the two end plates 27, surfaces 28 moderately kept somewhat larger and are preferably made of stainless steel and have a plurality of bolt holes 22 which receive the clamping elements 21 in the edge region. The lower end plate 27 has a tubular main connection 23 for the introduction of the first fluid F 1 , which is assigned to the right-hand slot openings 7 of the carrier plates 1, 2 , the main connection 23 as the main connection slot 23 ' on the top of the lower end plate 27 ends. In the opposite edge region of the upper end plate 28 , a corresponding main connection 24 with a correspondingly arranged main connection slot 24 ' is seen before, which in the example shown serves as an outlet for the first fluid F 1 . The entering into the main line 23 first fluid F 1 thus fills the slot openings 7, overflows in the individual layers, the membrane blanks and enters the gegenüberlie constricting slot openings 7 and exits through the upper main port 24 from. The flow in the opposite direction is of course also possible. If, according to the principle of diffusion, the second fluid F 2 overflows the rear side of the membrane, the arrangement of two further main connections 25 and 26 in the two end plates 27, 28 for the fluid F 2 is seen accordingly. The fluid F 2 occurs in the lower end plate 27 through the main connection 25 in the main slot connection 25 ' and from there into the slot openings 8th The back sides of the membrane blanks are, mutatis mutandis, flows over and the fluid F 2 enters into the opposing slot openings 8 and from there into the slot Hauptan circuit 26 'and the main terminal 26th The reverse flow direction is also possible here.

The main slot openings 23 ', 25', 24 ' and 26' can, as indicated in Fig. 1, be equipped with ring seals or other flat seals 29 , if not a special seal on the top and bottom of the packet-shaped separating device 30 is seen before. Corresponding seals 29 ' must then also be provided in the area of the blind connections for the other slot openings 7, 8 .

For carrying out an ultrafiltration, only one main connection, ie either the main connection 25 or the main connection 26, is not necessary for the fluid F 2 . Since the permeate does not flow over the back of the membrane sections, but only has to be subtracted from the entire area, it is only necessary to provide slot openings 8 on the third or fourth side of the rectangle. In order to ensure a comprehensive application from the outset with the carrier plates 1, 2 , these are designed for the two-part overflow. With ultrafiltration, too, it is advantageous if the permeate is drawn off from the back of the membrane blanks in both directions.

The carrier plates 1, 2 are made of plastic for cost reasons. Of course, they can also be made of stainless steel for special purposes.

The carrier plates 1, 2 according to FIGS. 2 and 5 and 8 are particularly suitable for filtration. For carrying out separation processes on the principle of diffusion, more carrier plates are suitable, as indicated in FIG. 6. In the case of a mass transfer based on the principle of diffusion, it is advantageous if the second active fluid F 2 also comes into contact with the largest possible surface area of the membrane on the rear side thereof. For this purpose, a fabric 39 is suitable, for example, which supports the membrane M 1 and is fastened in a frame-like window 40 of the carrier plate 1 . This can be done in that the thermoplastic deformation of a projection in the window 40, the fabric 39 is integrated into the frame of the carrier plate 1 and in this loading area also the outer membrane edge 6 is fixed. Otherwise, the design of the carrier plate corresponds to the detailed points shown in FIGS. 2 to 5, as far as the shape of the flow guidance and the shape of the seal are concerned.

The embodiment of FIGS. 7 to 10 shows a be especially designed from the point of view of easier handling, optimized separation performance and cheaper Her position separating device. The parts 1 to 30 described above are functionally the same as those in FIGS . 1 to 6, so that parts of the preceding explanations and description parts can be readily used.

Referring to FIG. 7, the separating device is designed as a standalone unit with vertical support plates 1, 2. The Ge advises Fig mutandis. 7 is composed of the vertical end plate 27 'having all 4 main terminals 23 through 26 for the two fluids F 1 and F 2 and plate as bores in the end 27' to end. The other end plate 28 ' is without connections and only on the two lower Spannele elements 21 horizontally displaceable and supported by a central threaded spindle 33 , which in turn is supported on a vertical abutment plate 34 . The abutment plate 34 is connected via 4 horizontal Spannele elements 21 to the end plate 22 ' . The two un lower clamping elements 21 serve simultaneously as a guide and holder for the as a cuboid or as a cassette 30 separating device which is clamped between the end plates 27 ' and 28' .

The connection-free end plate 28 ' facing the end plate 3' covers the back, ie the gutter 20 equipped with the side of the last carrier plate 1 according to FIG. 2 or FIG. 8 and is integrated with it by the sealing means 15 . To the connection side pointing to the connecting plate 3 '' and 3 ''' is formed in two parts and shown in Fig. 9a, b and 10a, b and described in more detail below. The two-part end plate 3 '' and 3 ''' are also an integral part of the actual separation device, so that both the support plates 1, 2 and the two end plates 3' and 3 '', 3 '''form the actual cassette 30 , which is used according to FIG. 7 in a simple manner between the two end plates 27 ' and 28' . Guide grooves 37 in the cassette 30 provide guidance and support on the two lower Spannele elements 21 and molded grip grooves 38 facilitate the handling of the cassette 30 when inserted between the two end plates 27 ', 28' . Two opposite sides of the cassette 30 each have the guide grooves 37 or gripping grooves 38 , so that the cassette 30 has its correct seat only rotated by 180 °, so that incorrect insertion is excluded.

This training has the advantage that no connections and screw connections have to be solved if a cassette 30 must be replaced with a new cassette.

This is only done by loosening the central spindle 33 .

The design of the carrier plate according to FIGS. 8, 8a, which is optimized from a fluidic point of view, corresponds in terms of its functional structure to that of the carrier plate according to FIGS. 2 to 5, as far as components 4 to 20 are concerned.

In the case of relatively large-area support plates 1, 2 made of plastic, there is a risk that preferred flow zones will form due to manufacturing tolerances over the total area of the flowed-over membrane, as a result of which the effectiveness of the overall membrane area suffers. According to the invention, each groove 5 has, with reference to the detail according to FIG. 8a, a plurality of flow barriers 31 which are distributed over the groove length and which end in the plane of the groove ridges 4 or below, where each groove 5 has at least one passage 19 at a collecting groove crossing 20 the opposite side of the carrier plate 1, 2 has connection. The plurality of flow barriers 31 are arranged approximately parallel to each other and obliquely to the grooves 5 extending barrier lines 32 . In the case of an approximately square membrane surface, the longest barrier line 32 runs at approximately 45 ° on the diagonal, while the other barrier lines 32 are arranged parallel to it at a distance. Depending on the ratio of the side length of a rectangular membrane surface, the barrier lengths 32 cross the grooves 5 at an angle of approximately 30 to 60 °. The barrier lines 32 of two support plates 1, 2 facing one another with their groove side are arranged in opposite directions, ie they intersect (shown in broken lines in FIG. 8). Under the liquid pressure of the overflowing fluid F 1 , a certain curvature of the membrane blanks occurs in the supporting grooves 5 , which is prevented in the area of the flow barriers 31 , so that a certain congestion occurs at these points and short-circuit paths are excluded. Due to the intersecting barrier lines 32 of two mutually facing plate sides, the diagonal flow is canceled again, so that a uniform flow across the entire membrane surface over the entire inflow side along the slot openings 7 is ensured.

The outer contour of the carrier plates 1, 2 differs from that of FIG. 2 by arranging the guide grooves 37 on opposite outer edges and arranging the grip grooves 38 also on opposite outer edges.

The two-part end plate 3 ''',3'' is also made of plastic and corresponds in its outer contour and with respect to the slot openings 7, 8 of the carrier plate 1, 2 as shown in FIG. 8. The back of the half end plate 3, not shown 3''' is shown in Fig. 9a, b is smoothly carried out and forming a cover for the uppermost support plate, and that the collecting grooves 20 having back as be in FIG. 2, with 2 TR records. Likewise, the channels 14 and the branch channels 13 are arranged.

According to Fig. 9a, b, the slot openings 7, 8 are surrounded by distributor and collector pipes 35 , which are approximately trough-shaped in cross section and form a full pipe in connection with the overlying trough shape of the distributor and collector pipes 35 according to FIG. 10. The distributor and manifolds 35 of both end plate halves 3 ''',3'' are framed by branch channels 13' and channels 14 ' and connected to the openings 11 through which the liquid sealing medium 15 in all branch channels and channels of all plates of the cassette 30th is injected. The end plate half 3 '' corresponds in structure to the end plate half 3 '' ' facing this side and is on the end plate 27' facing side substantially smooth. The in the manifold and collector pipes 35 angeord designated holes 36 are aligned with the holes of the main connections 23 to 26 . The holes 36 are bordered on the end plate 27 ' facing side with O-ring seals which seal against the end plate 27' when the cassette 30 is pressed by the central spindle 33 against the end plate 27 ' .

Depending on the geometric plate configuration and formation of the flow paths and arrangement of the necessary sealing elements, it may be sufficient or also expedient, at least in sections, distributed over the bottom of the carrier plate, openings 11, 12 and channel grooves 13, 14, 13 ', 14' to arrange, which communicate within the stack of plates, so that individual sections are sealed together across the stack height. In the illustrated embodiments, he followed the arrangement of the sealing elements so that all union channel grooves 13, 14, 13 ', 14' and openings 11, 12 communicate and thus all plates are sealed together by a single injection of plastic and permanently connected. The sealant 15 are made of thermoplastics such as polypropylene, polystyrene, polyamide, polyacetal resins, poly vinyl chloride (PVC), polyethylene (PE), polycarbonate, EVA, acrylic-styrene copolymer (ABS), styrene-acrylonitrile copolymer (SAN), CA formed or the sealant 15 is made of synthetic resin such as polyurethane resin, epoxy resin, urea-formaldehyde resin or formaldehyde-melamine, formaldehyde-phenol resin.

It is to produce a perfect sealing function however only necessary to perform a sealing function the plastic, e.g. B. silicone to use while the actual cohesion of the multitude of plates too a cassette through other mechanical clamping devices can be taken.

The separator can be used for everyone in the industry separation methods, i.e. as a dialyzer, as a filter, as Oxygenator, for separating milk ingredients, for Water treatment etc. as well as an artificial kidney or Lungs are used in the medical field.

By arranging several such cuboid separating devices 30 , the total membrane area can vary, by closing slot openings in a row on the outer carrier plates 1, 2 or by a special design of the end plates 3 , the individual packet-shaped separating lines 30 can be flow-connected in series or connect in parallel.

The membranes that can be connected to the carrier plates are in to understand the broadest sense, i.e. microporous membranes, Composite membranes, filter fleeces, filter fabrics and filters sieves. For performing ultrafiltration e.g. B. microporous membranes made of polysulfone used also allow chemical cleaning of the filter unit. Depending on the application and the requirements, also in With a view to multiple reuse of the cleaned th filter unit, but all commercially available ver to be developed membranes with the carrier plates be bound. The term semipermeable membrane is so too understand that the membrane contains only certain substances in one Direction due to the acting transport mechanisms (Filtration, diffusion) and through openings of one Allows membrane side to pass through, i.e. acts selectively.

Claims (1)

Separating device for fluids consisting of carrier plates and membrane blanks of a semi-permeable membrane, which can be guided on both sides of the membrane in separate flow paths and the separate guidance of the fluids is ensured by means of cord-shaped or band-shaped sealing elements held in the carrier plates, characterized in that the carrier plates ( 1, 2 ) for receiving the sealing elements to the plate level open channel grooves ( 13, 14, 13 ', 14' ) and in these openings ( 11, 12 ), which communicate at least in sections and a introduced in the flowable state and solidified therein Sealing material ( 15 ) included.