DE19945978A1 - Fluid distribution frame for multi-chamber stacks - Google Patents

Abstract

The invention relates to the design of fluid distribution frames for multi-chamber stacks for the uniform distribution of fluid flows to different chambers. The task here is to distribute the individual fluid flows over the chamber width in such a way that the flow through the chambers takes place completely and uniformly and at the same time every leak between the individual fluid flows is prevented. DOLLAR A This task is solved with the distribution frame shown below as follows: DOLLAR A The fluid supply and discharge takes place through distribution channels (1), (11) in the distribution frame (2) and inlet and outlet openings (3), (9) which can be incorporated into inserts (13) which have cover surfaces which are continuous on both sides. The supply takes place first in a pre-chamber (4), the discharge via a post-chamber (8), which are delimited to the chamber (10) by flow distributors (5) or flow collectors (7) and either integrated in the distribution frame (2) or with it are connected. Openings (6) in these distributors / collectors ensure uniform distribution into and discharge from the chamber (10).

Description

In parallel plate apparatuses such as membrane stacks, fuel cell stacks or plate heat exchangers, different process streams must be distributed as evenly as possible across different chambers. A large number of basic units with repeating chamber sequences are usually combined in a stack. The individual chambers are usually formed by frame plates ( 2 ), which are clamped between two end plates and, in addition to the cutouts for the actual chambers ( 10 ), contain distribution systems for supplying and discharging the process streams and spacers ( 12 ) for maintenance. Between the frame plates, for. B. membranes are clamped over the individual components are selectively transferred from one to another process stream (membrane separation process).

The chambers must be sealed with one another in order to prevent mixing or contamination to prevent individual flows and leakage. Common sealing variants are flat or o Ring seals or self-sealing frames or frames glued to the membranes. Continuous has also set itself the simplest possible, universally applicable frame design with which by turning or turning one and the same frame as many different ones as possible Have connection variants implemented.

The uniform supply of the individual chambers is usually achieved via the end plates by means of supply bores ( 1 ) going through all frames, from which one or more feeds ( 3 ) to the individual chambers ( 10 ) depart in each frame.

The uniform distribution of the currents across the chamber cross-section is essential to ensure homogeneous flow conditions in the chamber and to achieve uniform dwell times. Usual frame concepts take this into account by a variety of supply bores ( 1 ) across the chamber width, or accept poor distribution in favor of the simplest possible frame design.

Especially in the case of thin frames, an "open design" of the chamber inlets and outlets has prevailed for manufacturing reasons, ie the supply channels ( 3 ) are either milled into the panels on one side, or the panels are completely broken free at the corresponding points and are covered with flat seals . The lack of pressure on the seal in this critical area results in internal leakages.

This results in the task of addressing the disadvantages of common framework concepts mentioned above, such as internal leakage or uneven flow distribution across the cross section of the Eliminate chambers without the benefits of a simple and flexible use Trimming frame geometry.  

According to the invention, this object is achieved as follows:
The schematic diagram of the invention shown in Fig. 1 shows a flow through Fluidver distribution frame ( 2 ) with a plurality of supply ( 1 ) and discharge channels ( 11 ), the supply of a fluid stream into the chamber ( 10 ) and its discharge via one or more supply ( 1 ) or discharge channels ( 11 ) can take place. Via one or more inlet openings ( 3 ), the respective process streams are first led into a smaller prechamber ( 4 ) upstream of the main chamber ( 10 ), which is separated from the actual main chamber ( 10 ) by a flow distributor ( 5 ). The flow distributor ( 5 ) contains a number of openings which serve to distribute the fluid evenly. By targeted generation of a small, defined pressure loss in the flow distributor ( 5 ), which must be greater than the pressure loss for the flow through the pre-chamber ( 4 ) or the post-chamber ( 8 ), the flow is evened out over the cross-section of the main chamber ( 10 ). Accordingly, a flow collector ( 7 ) is located at the outlet of the main chamber, which separates the main chamber from a post-chamber ( 8 ) and ensures a uniform outflow from the chamber. The fluid is supplied to the discharge channel or channels ( 11 ) through one or more outlet openings ( 9 ), through which it leaves the stack. This arrangement allows the frame to flow through in the opposite direction. Optionally, a version without the flow collector ( 7 ) and the post-chamber ( 8 ) is also possible by a suitable design of the drain ( 9 ). In the main chamber ( 10 ), spacers or turbulence promoters (spacers) ( 12 ) can also be introduced and connected to the frame ( 2 ) or the flow distributors ( 5 ) and ( 7 ).

The frame ( 2 ), the flow distributors ( 5 ), ( 7 ) and the spacers ( 12 ), which are made of flat material, or produced by master forms and possibly reworked, can either be made from one part or from several parts put together and be connected to each other. Polymers, metals, ceramic materials or dense carbon modifications as well as combinations of these materials come into consideration as materials. Both the supply ( 3 ) and discharge openings ( 9 ) and the flow distributor ( 5 ), ( 7 ) can either be integrated in the frame ( 2 ) or in separate inserts ( 5 ), ( 13 ), which with the Frame connected in a suitable manner.

Figs. 2 and 3 show as an example the same frame (2), to be distributed in the once from the left supply channel (1) and once from the center channel. When distributing from the left supply channel, a flow distributor ( 5 ) is used, the penetration resistance of which decreases from left to right. This is achieved in Fig. 2 in that the length of the openings ( 6 ) changes over the chamber width. Instead, the distance and / or diameter of the openings across the chamber width can also be changed. When distributing from the right supply duct ( 1 ), the same flow distributor ( 5 ) can be installed in mirror image. When distributing from the middle supply channel ( 1 ) would come z. B. a flow distributor ( 5 ) with a shape according to FIG. 3 in question.

In order to avoid impressions of membranes in the opening of the prechamber (4) or The latter did mer (8), this can partially or completely in the chamber (10) facing part of the distribution frame (2) or, advantageously, in the flow distributor (5 ) or the flow collector ( 7 ) can be incorporated. Fig. 4 shows a corresponding configuration, in which a flow distributor consisting of two halves is used with an integrated antechamber. The prechamber ( 4 ) and the openings ( 6 ) are incorporated into one of the two or both halves, so that the structure shown is obtained by folding both halves and fitting into the corresponding openings in the distribution frame ( 2 ). The total thickness resulting from both halves of the flow distributor ( 5 ) must correspond to the frame thickness. The recess ( 4 ) for the Vorkam mer and the size of the passage openings ( 6 ) are to be chosen so that the flow pressure loss through the prechamber ( 4 ) is smaller than that through the passage openings ( 6 ), so that a uniform Distribution over the chamber width is done.

To simplify production, the openings ( 3 ) or ( 9 ) from the supply channels to the chambers ( 10 ) can be integrated into inserts ( 13 ) which are fitted into corresponding cutouts in the frame ( 2 ). Fig. 5 shows an embodiment.

In a two-part embodiment, the inserts ( 13 ) of the supply or discharge channels ( 1 ), ( 11 ) or the flow distributors ( 5 ) or collectors ( 6 ) can be made of flat material into which the flow channels ( 3 ), ( 6 ), ( 9 ) are incorporated in such a way that smooth, continuous cover surfaces result on the outside and the total thickness corresponds to the frame thickness. An outwardly flat cover surface is essential for the inserts ( 13 ) of the supply and discharge channels in order to avoid leaks that would occur if flexible membranes or flat seals were pressed into recesses on the surface. Fig. 6 shows a possible embodiment for the use ( 13 ) of Fig. 5. Instead of the straight channels, knobs or other spacers can also be incorporated or inserted, which keep the two halves at the required distance.

In Fig. 7 the possibility is shown, the inserts (13) and the flow distributor (5) to combine (7) to a part (14), which may also contain the pre- or post-chamber (4), (8).

The flow distributors ( 5 ), ( 7 ) and the inserts ( 13 ) or ( 14 ) can also be made entirely or partially from porous material (e.g. sintered material). Furthermore, as shown in FIG. 7, flow internals ( 15 ) or turbulence promoters ( 12 ) can be introduced into the pre-chamber ( 4 ) or the post-chamber ( 8 ) or into the flow distributors ( 5 ), ( 7 ) or the inserts Integrate ( 13 ) or ( 14 ) or connect to them.

If the distribution frame ( 2 ) is sufficiently narrow, or the fluid is supplied or removed via a plurality of supply or discharge channels ( 1 ), ( 11 ), the fluid distribution shown in FIG. 8 can also be expedient. In this case, a fluid distributor composed of two halves is used, which integrates the various distribution functions similarly to FIG. 7. In contrast to FIG. 7, the prechamber ( 4 ) can be omitted if the flow is appropriately designed in the integrated insert ( 16 ) if the flow is sufficiently transverse. In Fig. 8, this is effected by notches which run crosswise to one another in both halves and which form an angle to the frame axis of preferably 30-60 °. Alternatively, the distribution can also be carried out by staggered spacing knobs. A corresponding part can be used for the process.

Label list

1

Supply channels through the distribution framework (

2nd

)

2nd

Distribution framework

3rd

Inlet openings of the feed channels to the chamber (

10th

)

4th

Antechamber (flow inlet)

5

Flow distributor from the antechamber (flow inlet)

6

Openings in the flow distributor (

5

) or collectors (

7

)

7

Flow collector by chamber (

10th

)

8th

Post-chamber (flow outlet)

9

Outlet openings to the discharge channels (

11

)

10th

chamber

11

Exhaust channels

12th

Spacer in chamber

10th

or antechamber (

4th

), (

8th

)

13

Feeder inserts (

1

) or discharge channels (

11

)

14

Integrated inserts for flow distribution / collection and supply / discharge

15

Flow internals

16

Integrated inserts for flow distribution / collection and supply / discharge with crossed channels

Claims (18)

1. Fluid distribution frame for membrane stacking or parallel plate apparatus for even supply and discharge of the required fluid flows into / from fluid compartments ( 10 ), characterized in that the fluids from one or more supply channels ( 1 ) in the distribution frame ( 2 ) initially via one or several inlet openings ( 3 ) get into one or more antechambers ( 4 ), which together extend over the width of the active com partment area and from this antechamber via a flow distributor ( 5 ) connected to the frame ( 2 ) evenly over the width of the active area the chamber ( 10 ) are distributed, the distribution taking place through openings ( 6 ) in the flow distributor ( 5 ), the overall cross section of which is designed in such a way that they provide the fluid with a flow resistance which is greater than the flow resistance of the prechamber ( 4 ) and the exiting fluid in an analogous manner flows through the chamber ( 10 ) ungsverteiler ( 7 ), the post-chamber ( 8 ) and outlet openings ( 9 ) via the discharge channels ( 11 ) leaves again. 2. Fluid distribution frame according to claim 1, characterized in that the frame is composed of several parts which are connected to each other in a fluid-tight manner and which the channels ( 3 ) and ( 9 ) and the openings ( 6 ) in the flow distributors ( 5 ) and ( 7 ) set free. 3. Fluid distribution frame according to claim 1 and 2, characterized in that the shape of the antechambers ( 4 ) and ( 8 ), the type of openings ( 6 ) and the shape of the flow divider ( 5 ) and ( 7 ) are designed so that there is a uniform distribution of the entering and a uniform withdrawal of the exiting fluid over the width of the chamber ( 10 ). 4. Fluid distribution frame according to claim 1 to 3, characterized in that the flow distributors ( 5 ) and ( 7 ) are made independently of the rest of the fluid distribution frame ( 2 ) in the same thickness as this, so that different shapes of the flow distributor selected and connected to the frame can be, depending on which supply ( 1 ) or discharge channels ( 11 ) should be used to distribute or collect the fluid. 5. Fluid distribution frame according to claim 1 to 4, characterized in that the channels ( 3 ) from the supply channels ( 1 ) to the antechambers ( 4 ) or from the outlet openings ( 8 ) to the discharge channels ( 11 ) in inserts ( 13 ) are incorporated, which are manufactured independently of the fluid distribution frame ( 2 ) and later connected to it in a suitable manner or fitted into it. 6. Fluid distribution frame according to claim 1 to 5, characterized in that the flow distributors ( 5 ) and ( 7 ) or the inserts ( 13 ) are combined to form a part ( 14 ) which comprises the antechamber ( 4 ) and the after chamber ( 8 ) can contain and is connected in a suitable manner to the frame ( 2 ). 7. Fluid distribution frame according to claim 4 to 6, characterized in that the flow distributors ( 5 ) or ( 7 ) and the inserts ( 13 ) or ( 14 ) are composed of several parts of the same thickness as the frame ( 2 ), in through the openings ( 3 ), ( 6 ), ( 9 ) are incorporated. 8. Fluid distribution frame according to claim 1 to 7, characterized in that the channels ( 3 ) run completely within the frame ( 2 ) or the inserts ( 13 ) or ( 14 ), so that there are closed surfaces on both sides. 9. Fluid distribution frame according to claim 5 to 7, characterized in that the flow distributors ( 5 ) and ( 7 ) or the inserts ( 13 ) or ( 14 ) are wholly or partly made of a porous material (z. B. sintered, Fabric, braid, press material al). 10. Fluid distribution frame according to claim 1 to 9, characterized in that as Materials Polymers, metals, ceramic materials or dense carbon modifications NEN and combinations of these materials are used. 11. Fluid distribution frame according to claim 1 to 10, characterized in that the frame ( 2 ) or parts thereof are made of flat material or produced by master forms (such as (injection) molding, etc.) and optionally reworked. 12. Fluid distribution frame according to claim 1 to 11, characterized in that the flow distributor at the outlet ( 7 ) and the outlet chamber ( 8 ) are missing, so that the discharge from the chamber ( 10 ) takes place directly in the suitably designed outlet openings ( 9 ). 13. A fluid distribution frame according to claim 1 to 12, characterized in that the antechambers ( 4 ) and ( 8 ) are provided with flow internals ( 15 ) or contain spacers / turbulence promoters ( 12 ). 14. Fluid distribution frame according to claim 1 to 13, characterized in that the main chamber ( 10 ) contains one or more spacers / turbulence promoters ( 12 ) or flow internals. 15. Fluid distribution frame according to claim 1-14, characterized in that the spacer / turbulence promoters ( 12 ) in the frame ( 2 ) or the flow distributor ( 5 ), ( 7 ) integrated or otherwise connected to them. 16. Fluid distribution frame according to claim 1-15, characterized in that the pre-chamber ( 4 ) or the post-chamber ( 8 ) wholly or partially incorporated into the frame ( 2 ) or in the flow distributor ( 5 ) or the flow collector ( 7 ) are so that the open gap ( 4 ) or ( 8 ) between the frame ( 2 ) and the flow distributor ( 5 ) or ( 7 ) becomes very small or disappears. 17. Fluid distribution frame according to claim 1 to 16, characterized in that the openings ( 3 ), ( 6 ), ( 9 ) are introduced into the two halves of the inserts ( 13 ) and ( 14 ) that crossed, open to each other Provide channels that are preferably at an angle of 30-60 ° to the frame axis. 18. Fluid distribution frame according to claim 1 to 17, characterized in that the openings ( 3 ), ( 6 ), ( 9 ) result from the fact that in the two halves offset stubs are inserted or inserted in the direction of flow.