Title: Method Of Locating And Repairing Damaged Hollow Fiber Modules
And Header Assembly
[0001] For the United States of America, this application claims the benefit under 35 USC 119(e) of US Application No. 60/617,849 filed October 12, 2004 and the entire disclosure of US Application No. 60/617,849 is incorporated herein.
Field of the invention(s)
[0002] This invention relates to hollow fiber membranes and aspects of the invention may also relate to header or module assemblies, methods of locating a damaged fiber or methods of repairing a module with a damaged fiber.
Background of the invention(s)
[0003] The following discussion is not an admission that anything discussed below is citable as prior art or part of the knowledge of people skilled in the art in any country. [0004] Hollow fiber membranes are used in a variety of filtration, separation or transfer processes. However, the fibers occasionally break. Such breaks threaten the quality of the filtrate or other process products. Integrity tests done on a module or larger scale may be used to locate a defective module. The defective module can then be removed from service, but the particular broken fiber still needs to be located and the module still needs to be repaired. One method of locating a damaged fiber involves immersing a module into a tank of water. A source of pressurized air is connected to a header of the module to pressurize the lumens of the fibers. The pressurized air passes through the broken fiber and produces a train of bubbles. A technician follows the train of bubbles to locate the damaged fiber. To repair the module, the technician plugs the end or ends of the broken fiber. This method, however, suffers from various problems. For example, it is often difficult to follow the bubble trail through a large tank to the damaged fiber, particularly in modules having a large number of fine fibers. In some such
modules, it is also not possible to repair fibers in certain parts of the fiber bundle. Further, locating and repairing the loose ends of broken fibers is time and labour intensive.
Summary of the invention(s) [0005] One object of an aspect of an invention may be to improve on the prior art, or at least provide a useful alternative to the prior art. Other alternative objects of aspects an invention or inventions may include providing a header assembly, providing a method of locating damaged fibers or providing a method of repairing a module having a damaged fiber. The following summary is intended to introduce the reader to the invention(s) but is not intended to define any invention which may reside in a combination or sub-combination of steps or elements provided in this or other parts of this document, for example in the claims.
[0006] In one aspect of an invention a header assembly has a plurality of hollow fiber membranes with their ends sealed in a block of a potting medium. The potting medium is sealed to a cover such that the ends of the membranes are open to a plenum formed between the cover and the potting medium. The cover has a port allowing fluid communication between the outside and inside of the plenum. The cover may optionally have additional re- sealable openings allowing temporary access to the plenum. The cover is translucent or transparent, allowing the ends of the membranes to be observed from outside of the cover. The cover and port, or ports, are further arranged such that a liquid can be placed in the plenum to a depth covering the ends of the membranes while a vacuum is applied to a port. [0007] Another aspect of an invention provides a method of locating a broken or damaged fiber. The separating surfaces of the fibers are exposed to a gas, for example air. A liquid, for example water, is placed over the ends of the fibers. A pressure differential is then applied between the free surface of the liquid over the ends of the fibers and the separating surface of the membranes, at a pressure sufficient to create a bubble of the gas through a defect of a size that would require repair. The liquid is then observed, for
example through a transparent cover over the liquid, for the presence of a bubble. A bubble produced at the end of a damaged fiber, if any, indicates the fiber end, and therefore the fiber, having the defect. Optionally, the location of the fiber end corresponding to the damaged fiber may be marked for later re- identification.
[0008] Another aspect of an invention provides various methods of repairing a module having a damaged fiber. The module is repaired by sealing the open end or ends of the damaged fiber. In one method, an end is sealed by applying a sealing material to the fiber end through a port or opening in a header cover. Optionally, the fiber end may first be prepared to accept the sealing material. Further optionally, the sealing material may be cured by applying an energy source though the wall of the cover. Yet further optionally, an opening may be created in the wall of the cover to enhance access to the fiber with the opening closed after the fiber end has been sealed. In another method, an energy source is directed through the cover to melt the fiber end shut.
Brief description of the drawings
[0009] Embodiments of the invention or inventions will now be described with reference to the following figures. [0010] Figures 1 through 7 show a portion of a first header assembly, steps in a first method of locating a damaged fiber and a first method of repairing a module.
[0011] Figure 8 shows a portion of a second header assembly.
[0012] Figure 9 shows a second method of repairing a damaged module.
[0013] Figures 10 through 12 show alternate covers for header assemblies.
[0014] Figure 13 shows a second method of locating a damaged fiber.
[0015] Figure 14 shows a portion of a third header assembly.
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Description of exemplary embodiments
[0016] Referring to Figures 1 to 7, a module 10 has a plurality of hollow fiber membranes 12 with their ends 16 sealed in a block of potting material 14. In the Figures, the number of membranes 12 has been greatly reduced for clarity. The ends 16 of the membranes 12 are open at one face 18 of the potting material 14. In the embodiment illustrated, the ends 16 of the membranes 12 are machined flush with the face 28 of the potting material although, in other embodiments, the ends 16 of the membranes may protrude from the face 18 of the potting material 14. The module 10 may be of one of various configurations. For example, the other ends of the membranes 12, possibly not shown, may be held in a second block of potting material with their ends closed or open to a second cover which may have no ports or may have ports closed during part of the location or repair procedure, for example during the steps described below in relation to Figure 2. Second ends of the membranes 12 may also be sealed individually but not held in a second block of potting material or the membranes 12 may be looped and have their second ends potted in the block of potting material 14 shown in the Figures.
[0017] A translucent or transparent cover 20 forms a plenum 23 with the potting material 14. In the embodiment illustrated, the bottom edges of the cover 20 are sealed to the face 18 of the potting material 14, which is flat, by glue or welding. However, in other embodiments, alternate constructions may be used. For example, the potting material 14 may extend to, and adhere or be glued or welded to, the inside of the walls of the cover 20. The cover 20 may also be removably attached, for example by screwing through a gasketed flange into the potting material 14.
[0018] The cover 20 has a port 24 which allows fluid communication between the outside of the plenum 22, and the inside of the plenum 22, and to the ends 16 of the membranes 12. In the embodiment illustrated, the port 24 is a permeate port used, in normal operation of the module 10, to apply a suction to the membranes 12. The module 10 illustrated is ordinarily immersed in a tank of water or wastewater at ambient pressure, with the
operating surfaces 30 of the membranes 12 in contact with the water or wastewater, and used to withdraw a filtered water permeate. However, in other embodiments, the module 10 and port 24 may have other uses, for example the withdrawal of fluids created by pressurizing a fluid against the operating surface 30 of the membrane 12 or the injection of a fluid into the membranes 12 to be permeated or filtered out through the separating surfaces 30 of the membranes 12. The module 10 may have a similar header assembly 32, comprising a cover 20, potting material 14 and open ends 16 of the membranes 12, at the opposed ends of the membranes 12, or the opposed ends of the membranes may be sealed but free, sealed in small, movable groups, sealed into another block of potting material, or otherwise arranged. Where the module 10 has membranes 12, each with a pair of open ends 16 in opposed header assemblies 32, both header assemblies 32 need to be treated as discussed below to repair the module 10. The cover 20 illustrated also has an access opening 26 with a selectively removable plug 28 although in other embodiments the port 24 may be used to perform the functions of the access opening 26, or a temporary opening may be made, or example by drilling a hole through the cover 20 and later sealing the hole when required. [0019] In Figure 1 , the module 10 has been found to contain a damaged fiber 12d by an integrity test on the module 10. The damaged fiber may, for example, be broken or have a hole of unacceptable size. However, the location of the damaged fiber 12d is not yet known. The module 10 is removed from its tank and is held with the separating surfaces 30 of the fibers 12 exposed to a gas, for example air at ambient pressure. A layer of liquid 34, for example water, is poured into the plenum 22, for example through the port 24. The liquid 34 covers the ends 16 of the membranes 12, for example to a depth of about 1 cm.
[0020] In Figure 2, a vacuum is applied to the port 24, at a pressure sufficient to draw gas, in an amount sufficient to create a bubble, through a defect requiring repair. Gas pulled through the damaged membrane 12d
forms bubbles 36 in the liquid 34. Observation of the bubbles through the transparent or translucent cover 20 allows the end 16d of the damaged membrane 12d to be identified, for example by tracing the line of bubbles 36 back to the end 16d of the damaged fiber 12d or observing which end 16 the bubbles 36 emerge from. Optionally, the end 16d of the damaged membrane 12d may be marked to aid in later re-location, for example by placing a mark on the outside surface of the cover 20 directly over the end 16d of the damaged membrane 12d. Alternately, a laser pointer or other light emitting device may be held outside of the cover 20 so that it illuminates the end 16d of the damaged membrane 12d.
[0021] In Figure 3, the vacuum source is closed or disconnected and the plug 28 removed from the opening 26. The liquid 34 is also removed from the plenum 22. This may be done, for example, by draining though the opening 26 or port 24, by sucking the liquid 34 into the membranes 12 by applying a vacuum to their other ends, or by applying a pressurized gas to the port 24. Alternatively, the liquid 34 may be removed by leaving the opening 26 open while applying a vacuum to the port 24 until the liquid 34 is evaporated or carried away.
[0022] In Figure 4, a tool 40 is optionally inserted though the opening 26 to prepare the surface of the end 16d of the damaged fiber. The tool 40, and its use, may vary according the specific sealing method that will be used.
For example, the tool 40 may be a vacuum or blower wand used to further dry the end 16d of the damaged membrane 12d. Alternately, the tool 40 may have a moving head and be used to smooth or roughen a portion of the face 18 of the potting material 14 or the end 16d of the damaged membrane 12d.
Further alternatively, the tool 40 may be a tube used to disperse one or more chemical substances used to pre-treat the area to be sealed.
[0023] In Figure 5, the end 16d of the damaged membrane 12d is sealed. A second tool 42 is inserted into the plenum 22, for example through the opening 26, and used to dispense a sealing material 44 onto, or into, the
end 16d of the damaged membrane 12d. The sealing material 44 may be, for example, a resin, silicone or other substance.
[0024] In Figure 6, the sealing material 44 is optionally treated to decrease its curing time. For example, an energy source 46 may be used from outside of the cover 20 to send energy to the sealing material. The energy may be in the form of electromagnetic waves or radiation such as light, infrared or ultraviolet radiation, or microwaves.
[0025] In Figure 7, the access plug 28 has been replaced. The module
10 has been repaired. If a damaged membrane 12 has a second end that is open, the second open end may also be closed by repeating the location and repair steps to further repair the module 10. The integrity of the repair may be tested by repeating an integrity test on the module 10. Alternately, the steps described in relation to Figures 1 and 2 may be repeated.
[0026] Figure 8 shows a second header assembly 50. The second header assembly 50 has a block of potting material 14 and membranes 12 as before, but a second cover 52 has one or more ports 24, but no special access openings for use only in locating or sealing damaged membranes 12. A third tool 54, or other tools, used with this second header assembly 20 are bent, curved, flexible or otherwise adapted to allow use through a port 24. [0027] Figure 9 shows a second method of repairing a module 10. The second method is shown as used with the second header assembly 50 of Figure 8, although it may also be used with other header assemblies. In the second method, the energy source 46 is used to provide energy at sufficient intensity to melt the end 16d of the damaged fiber 12d closed, optionally after vaporizing any remaining liquid from the end 16a of the damaged membrane 12a.
[0028] Figures 10 to 12 show further alternate covers. In Figure 10, a third cover 60 has an elongated shape for use with an elongated or rectangular block of potting material. Two ports 24, one in each half of the third cover 60, are used to provide better access through the ports 24 to the
ends of the membranes. In Figures 11 and 12, fourth and fifth covers 62, 64 are made in the shape of a solid of rotation for use with a cylindrical block of potting material 12. A single port 24 is placed on the axis of rotation to provide better access to membranes located around the edges of the bundle of membranes. The fourth cover 62 is a portion of a sphere while the fifth cover 64 is a cone. The height of the fifth cover 64 is made large to facilitate use of straight tools through the port 24. In any of the covers 20, 52, 60, 62, 64, additional ports 24 or openings 26 may be provided as desired to improve access to the membrane ends, or temporary openings may be made, for example by drilling holes through a wall of the cover 20, 52, 60, 62, 64, to facilitate locating or repair procedures, and closing the temporary holes, for example by welding or gluing a plug into the temporary hole, before the module 10 is returned to service.
[0029] Figure 13 shows a second method of locating a damaged membrane. The second method is like the first except that the pressure differential is applied by exposing the separating surface 30 of the membranes 12 to a pressurized gas such as air. To do this, the second header assembly 50 is sealed to a pressure vessel 70 containing the module
10. Pressurized air is provided to the pressure vessel 70 through a fitting 72. The pressure vessel 70 may be a part made particularly for use in a locating or repair procedure or may be all or part of a shell used with the module in normal operation. The port 24 may be exposed to air at ambient pressure.
The method is shown with a module 20 having a second header assembly 50 at one end and closed fibers on the other end, but may also be used with other modules.
[0030] Figure 14 shows a third header assembly 80 having a sixth cover 82. The sixth cover 82 is removable and replaceable against the potting material 14. The sixth cover 82 is removably attached to the potting material 14 by means of screws 84 screwed through a flange 86 of the sixth cover 82 and a gasket 88 between the flange 86 and potting material 14. The sixth cover 82 may be used in normal operation of the module 10 or may be used
only for the locating or repair procedure. In the latter case, the sixth cover 82 is replaced with a different cover when the module 10 is used in service. In this way, the design of the sixth cover 82 can be tailored for the locating or repair procedure while a separate operating cover has a design tailored for the normal use of the membrane. Optionally, the sixth cover 82 may be disposable.
[0031] The embodiments described above give examples of the invention but do not limit the scope of the invention and the invention may be practiced with alternate apparatus elements or with alternate method steps. The invention may also be applied to devices of similar geometry, for example shell and tube heat exchangers.