WO2018150055A1 - Système de mélange à émulsion d'air réversible à basse pression destiné à être utilisé avec un réacteur à biofilm aéré à membrane - Google Patents

Système de mélange à émulsion d'air réversible à basse pression destiné à être utilisé avec un réacteur à biofilm aéré à membrane Download PDF

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Publication number
WO2018150055A1
WO2018150055A1 PCT/EP2018/054181 EP2018054181W WO2018150055A1 WO 2018150055 A1 WO2018150055 A1 WO 2018150055A1 EP 2018054181 W EP2018054181 W EP 2018054181W WO 2018150055 A1 WO2018150055 A1 WO 2018150055A1
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WO
WIPO (PCT)
Prior art keywords
membrane module
liquid
channel
airlift
enclosure system
Prior art date
Application number
PCT/EP2018/054181
Other languages
English (en)
Inventor
Eoin Syron
Donal LYNCH
Barry Heffernan
Wayne Byrne
Mike SEMMENS
Original Assignee
Oxymem Limited
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Oxymem Limited filed Critical Oxymem Limited
Priority to PL18709946T priority Critical patent/PL3582883T3/pl
Priority to CN201880012853.3A priority patent/CN110461448B/zh
Priority to JP2019565982A priority patent/JP7011671B2/ja
Priority to CA3052371A priority patent/CA3052371A1/fr
Priority to EP18709946.0A priority patent/EP3582883B1/fr
Priority to ES18709946T priority patent/ES2884099T3/es
Priority to BR112019017266A priority patent/BR112019017266A2/pt
Priority to US16/487,281 priority patent/US11434155B2/en
Priority to DK18709946.0T priority patent/DK3582883T3/da
Publication of WO2018150055A1 publication Critical patent/WO2018150055A1/fr

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Classifications

    • CCHEMISTRY; METALLURGY
    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F3/00Biological treatment of water, waste water, or sewage
    • C02F3/02Aerobic processes
    • C02F3/10Packings; Fillings; Grids
    • C02F3/102Permeable membranes
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D63/00Apparatus in general for separation processes using semi-permeable membranes
    • B01D63/02Hollow fibre modules
    • B01D63/04Hollow fibre modules comprising multiple hollow fibre assemblies
    • B01D63/043Hollow fibre modules comprising multiple hollow fibre assemblies with separate tube sheets
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D63/00Apparatus in general for separation processes using semi-permeable membranes
    • B01D63/02Hollow fibre modules
    • B01D63/04Hollow fibre modules comprising multiple hollow fibre assemblies
    • B01D63/046Hollow fibre modules comprising multiple hollow fibre assemblies in separate housings
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01FMIXING, e.g. DISSOLVING, EMULSIFYING OR DISPERSING
    • B01F23/00Mixing according to the phases to be mixed, e.g. dispersing or emulsifying
    • B01F23/20Mixing gases with liquids
    • B01F23/23Mixing gases with liquids by introducing gases into liquid media, e.g. for producing aerated liquids
    • B01F23/232Mixing gases with liquids by introducing gases into liquid media, e.g. for producing aerated liquids using flow-mixing means for introducing the gases, e.g. baffles
    • B01F23/2323Mixing gases with liquids by introducing gases into liquid media, e.g. for producing aerated liquids using flow-mixing means for introducing the gases, e.g. baffles by circulating the flow in guiding constructions or conduits
    • B01F23/23231Mixing gases with liquids by introducing gases into liquid media, e.g. for producing aerated liquids using flow-mixing means for introducing the gases, e.g. baffles by circulating the flow in guiding constructions or conduits being at least partially immersed in the liquid, e.g. in a closed circuit
    • B01F23/232311Mixing gases with liquids by introducing gases into liquid media, e.g. for producing aerated liquids using flow-mixing means for introducing the gases, e.g. baffles by circulating the flow in guiding constructions or conduits being at least partially immersed in the liquid, e.g. in a closed circuit the conduits being vertical draft pipes with a lower intake end and an upper exit end
    • CCHEMISTRY; METALLURGY
    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F3/00Biological treatment of water, waste water, or sewage
    • C02F3/02Aerobic processes
    • C02F3/12Activated sludge processes
    • C02F3/22Activated sludge processes using circulation pipes
    • C02F3/223Activated sludge processes using circulation pipes using "air-lift"
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D2313/00Details relating to membrane modules or apparatus
    • B01D2313/20Specific housing
    • B01D2313/203Open housings
    • B01D2313/2031Frame or cage-like structures
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D2313/00Details relating to membrane modules or apparatus
    • B01D2313/26Specific gas distributors or gas intakes
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D2315/00Details relating to the membrane module operation
    • B01D2315/06Submerged-type; Immersion type
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D2317/00Membrane module arrangements within a plant or an apparatus
    • B01D2317/04Elements in parallel
    • CCHEMISTRY; METALLURGY
    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F2203/00Apparatus and plants for the biological treatment of water, waste water or sewage
    • C02F2203/006Apparatus and plants for the biological treatment of water, waste water or sewage details of construction, e.g. specially adapted seals, modules, connections
    • CCHEMISTRY; METALLURGY
    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F3/00Biological treatment of water, waste water, or sewage
    • C02F3/02Aerobic processes
    • C02F3/12Activated sludge processes
    • C02F3/1278Provisions for mixing or aeration of the mixed liquor
    • C02F3/1284Mixing devices
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02WCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO WASTEWATER TREATMENT OR WASTE MANAGEMENT
    • Y02W10/00Technologies for wastewater treatment
    • Y02W10/10Biological treatment of water, waste water, or sewage

Definitions

  • a low-pressure, reversible airlift mixing system for use with a Membrane Aerated Biofilm Reactor Field of the Invention
  • the invention relates to a low-pressure, airlift mixing system for use with a membrane aeration module in membrane supported biofilm reactors, which are used to treat water or wastewater.
  • the invention relates to a low-pressure, airlift mixing system for use with a membrane aeration module in membrane supported biofilm reactors, which incorporate a low-pressure airlift pump to encourage good liquid flow through the membrane module when the modules are installed in a bioreactor or tank.
  • Membrane Supported Biofilm Reactors are bioreactors in which oxygen (or other gases) can be supplied to water or wastewater or to an attached biofilm via submerged, gas-permeable, membranes.
  • the membranes may be hollow fibre, planar or spiral wound, and the membranes can be made of a hydrophobic porous or, alternatively, dense gas-permeable material (e.g. polydimethylsiloxane (PDMS), polymethylpentene (PMP)).
  • PDMS polydimethylsiloxane
  • PMP polymethylpentene
  • the membranes are connected at one end to a gas supply and the other end can either be closed or open to allow an exhaust of the used gas.
  • the membranes can be arranged into arrays or cassettes which can then be further connected to form modules.
  • the reactor When the gas supplied to the membrane is oxygen in the form of air, oxygen-enriched air, or pure oxygen, the reactor is more commonly known as the Membrane Aerated Biofilm Reactor (MABR).
  • MABR Membrane Aerated Biofilm Reactor
  • the oxygen may be supplied to the one side of the membrane, which then allows oxygen to diffuse through the membrane and dissolve into the water on the other side, the water boundary layer over the membrane surface, or diffuse directly into a biofilm which is growing attached to the membrane. If the oxygen is not consumed in the biofilm it can continue to diffuse into the water around the biofilm.
  • Oxygen flux across the membrane is proportional to the concentration gradient of oxygen across the membrane so that a high flux can be achieved by operating with high oxygen partial pressures inside the membrane and very low dissolved oxygen concentrations at the outside surface of the membrane.
  • the activity of this biofilm on the liquid side of the membrane has a profound influence on the flux of oxygen through the membrane as the bacteria consume oxygen and influence the concentration gradient across the membrane wall. Since the bacteria in the biofilm require both nutrients (substrate) from the wastewater and the oxygen from the membrane, the activity of the bacteria is greatest when both the dissolved oxygen concentration and substrate concentration are high.
  • the activity of the bacteria may be limited either by limiting the supplying of oxygen, which is controlled by the rate of oxygen diffusion across the membrane, or by a limiting the supply of dissolved substrates, which is influenced by substrate concentration in the wastewater and the velocity of the wastewater over the membranes.
  • the thickness of the biofilm, and the biological activity within the biofilm control both the oxygen flux transfer across the membrane wall and the rate of substrate oxidation. As thicker biofilms develop aerobic, anoxic and anaerobic layers may form and the bacteria growing in these regions of the biofilm can remove both organic and inorganic contaminants (e.g. BOD and Nitrogen-based Pollutants).
  • Airlift pumps have been used in many applications for pumping water from one location to another when the pressure difference is low.
  • Example applications include aquaculture, where airlift pumps are often used to move water from one tank to another.
  • US Patent Publication No. 2007/0182033 which describes a bubble generator at the bottom of a vertical column, which when immersed in a tank filled with water can encourage good mixing throughout the tank.
  • the design of the inverted siphon, which is incorporated into the bubble generator at the base of the column, is to generate an intermittent release of large bubbles.
  • US Patent Publication No. 2016/0009578 incorporates a compartmentalized shroud with inverted siphons for aeration of an MABR, with an aerator having a separate air supply from the membranes.
  • International Patent Publication No. WO 2016/209235 relates to the deployment of floating membrane modules.
  • German Patent Application No. 100 04 863 describes an enclosure system comprising a plurality of panels used to enclose a membrane aeration module having hollow fibre membranes, and which induces air underneath the membranes to create an airlift system. This continuous upward flow around the membranes is required to ensure that the membranes are always vertical as the membranes are only attached to a manifold at one (lower) end.
  • the biofilm In the MABR, the biofilm is naturally immobilized on an oxygen permeable membrane. Oxygen diffuses through the membrane into the biofilm where oxidation of pollutants, supplied at the biofilm-liquid interface, takes place.
  • the oxygen supply rate is controlled by the intra-membrane oxygen partial pressure (a process parameter) and membrane surface area (a design parameter).
  • oxygen is provided by pumping air to the bottom of a wastewater treatment tank. The air then enters the liquid via diffusers forming bubbles which rise up through the wastewater, transferring oxygen to the wastewater and also providing mixing in the treatment tank.
  • the MABR has no air being pumped to create bubbles which provide sufficient mixing, maintaining high performance rates over long-term trials has proven to be very difficult.
  • the Applicants have provided a solution for sufficiently mixing the wastewater fluid in a MABR treatment housing or tank while maintaining low energy requirements to mix the liquid in the MABR treatment housing.
  • an enclosure for use with a Membrane-Aerated Biofilm Reactor of the type comprising a housing having an upper and lower headspace; an array of gas-permeable hollow fibre membranes arranged into cassettes disposed within the housing and extending from the upper headspace to the lower headspace, which incorporates a reversible, low-pressure, airlift mixing system to encourage a vertical wastewater flow over the membranes.
  • MABR Membrane-Aerated Biofilm Reactor
  • an enclosure for use with a Membrane-Aerated Biofilm Reactor of the type comprising a housing having an upper and lower headspace; an array of gas-permeable hollow fibre membranes arranged into cassettes, with the cassettes being further arranged into a module, disposed within the housing and extending from the upper headspace to the lower headspace, which incorporates a reversible, low-pressure, airlift mixing system to encourage a vertical wastewater (liquid) flow over the membranes, wherein the membranes can be arranged vertically in the module, in which case the resulting liquid flow would be parallel to the membranes, or the membranes could be arranged horizontally in the module resulting in a cross-flow configuration.
  • MABR Membrane-Aerated Biofilm Reactor
  • An enclosure system for use with a membrane module of the type having an upper and lower headspace separated by an array of gas-permeable hollow fibre membrane cassettes characterised in that the enclosure system comprises an airlift mixing system configured to transport liquid either from inside the membrane module to outside of the membrane module or from outside of the membrane module to inside the membrane module, and a plurality of panels configured to seal the membrane module to form an enclosed membrane module.
  • An enclosure system for use with a membrane module of the type having an upper and lower headspace separated by an array of gas-permeable hollow fibre membranes characterised in that the enclosure system comprises:
  • an airlift mixing system comprising an airlift channel and a first downcomer, which are in fluid communication with each other at their bottom, forming two vertical channels of a substantially U-shaped tube, which is open at both ends, and configured to transport liquid either from inside the membrane module to outside of the membrane module or from outside of the membrane module to inside the membrane module;
  • enclosure is open at the top and bottom and which is encased within the enclosure system.
  • An enclosure system for use with a membrane module of the type having an upper and lower headspace separated by an array of gas-permeable hollow fibre membrane cassettes, characterised in that the enclosure system comprises an airlift mixing system configured to transport liquid either from inside the membrane module to outside of the membrane module or from outside of the membrane module to inside the membrane module, and a plurality of panels configured to seal the membrane module to form an enclosed membrane module, wherein the membrane module is open at the bottom and top of the module resulting in direct fluid communication with the liquid beneath the module with the panels extending above the surface of the liquid such that the flow of liquid entering from the bottom of the module must leave through the airlift mixing system, or that the flow of liquid entering the module through the airlift mixing system must leave through the open bottom of the module.
  • the enclosure system further comprises a modular collar configured to attach to the enclosed membrane module and extend vertically above the surface of the liquid within the system. This increases the height of the upper headspace beyond the surface of the liquid.
  • the plurality of panels extends vertically above the upper headspace and extend beyond the surface of the liquid within the system.
  • the airlift mixing system comprises an airlift channel and a first downcomer.
  • the first downcomer and the airlift channel are in fluid communication with and are adjacent to each other, forming two vertical channels of a substantially U-shaped tube. Gas can then be injected into either side of this airlift mixing system creating an upward flow in the airlift channel and inducing a downward flow in the other channel of the U-shaped tube (the first downcomer). In this way flow is induced from one vertical channel of the U-shaped tube to the other, adjacent, vertical channel.
  • the airlift mixing system contains a third vertical channel, giving the airlift mixing system a substantially W-shape, wherein the third vertical channel is a second downcomer and wherein one of the vertical channels is the air-lift channel, which is in fluid communication with the first and second downcomer.
  • the enclosure system further comprises a vertical return channel, in which the vertical return channel is in fluid communication with the adjacent vertical channel of the substantially U-shaped tube or W- shaped tube.
  • the substantially U-shaped tube (and W-shaped tube) is open at both ends, with one open end of the substantially U-shaped tube (or W-shaped tube) distal the vertical return channel forms a port with access to the inside of the enclosed membrane module.
  • the other open end of the substantially U-shaped tube (or tubes of the substantially W-shaped tube), proximal the vertical return channel forms a port with access to outside of the enclosed membrane module.
  • the vertical return channel is in fluid communication with either the airlift channel or the first and/or second downcomer and extends from the top of the enclosure to the bottom of the enclosure or to the top of the vertical return channel of the module directly below.
  • the vertical return channel is open to the environment outside of the enclosed membrane module and configured to provide a continuous channel to supply liquid from one location within the holding tank, or another holding tank or compartment within a treatment system, to either the substantially U-shaped tube or another location in the holding tank.
  • the first downcomer is in fluid communication with liquid inside the enclosed membrane module and the airlift channel is in fluid communication with liquid outside of the enclosed membrane module or the vertical return channel.
  • first downcomer and second downcomer are in fluid communication with liquid inside the enclosed membrane module and the airlift channel is in fluid communication with liquid outside of the enclosed membrane module or the vertical return channel.
  • the first and/or second downcomer is in fluid communication with liquid outside of the enclosed membrane module or the vertical return channel and the airlift channel is in fluid communication with liquid inside of the enclose membrane module.
  • the airlift channel further comprises an air injection port configured to accept and deliver air into the airlift channel such that either the vertical channel of the U-shaped or W-shaped airlift mixing system can become the airlift channel and reverse the direction of the vertical flow of liquid within the enclosed membrane module.
  • the air that is supplied to the airlift channel is sourced from either exhaust air from the membranes, supplemental air from an external source, or both.
  • the substantially U-shaped tube comprises an air injection port on both sides of the tube, configured to accept and deliver air into either vertical channel of the substantially U-shaped tube so that either vertical channel of the substantially U- shaped tube can become the airlift channel, such that the direction of the vertical flow of liquid within the enclosed membrane module can be reversed.
  • the air that is supplied to the airlift channel is sourced from either exhaust air from the membranes, supplemental air from an external source, or both.
  • the air injection port is configured to release air continuously, in a pulsed or periodic manner, or a combination of both.
  • the air injection port is connected to an air syphon configured to allow air to accumulate and be released periodically to the air injection port.
  • the air injection port is configured to introduce air axially, radially, both axially and radially, or at an angle so as to induce turbulent water flow within the airlift channel.
  • the air injection port is less than 3.0 m below the water surface within the modular collar of the framing system.
  • the airlift mixing system is configured to control the level of liquid within the enclosed membrane module relative to the level of liquid outside the enclosed membrane module.
  • At least one panel in a four-sided enclosed membrane module of the enclosure system is configured to each accommodate the airlift mixing system.
  • At least two, three or all four panels in a four-sided enclosed membrane module of the enclosure system are each configured to accommodate the airlift mixing system.
  • the airlift mixing system is configured to pump liquid in an upward or downward direction through the enclosed membrane module.
  • the enclosure system further comprises a liquid flow distribution means in the headspace of the enclosed membrane module configured to provide uniform water flow throughout the enclosed membrane module. The liquid entering the enclosed membrane module from the airlift mixing system is distributed evenly along the surface of the liquid inside the module. Alternatively, the water leaving the enclosed membrane module and entering the first downcomer of the airlift mixing system is sourced evenly across the liquid surface of the enclosed membrane module.
  • the system further comprises one or more weirs attached to the open end of the vertical channel in fluid communication with the inside of the enclosed membrane module, each weir having uniform v-notches or v-notches of varying size along the length of the weir or along the mouth of a bell-mouth water intake, also attached to the open end of the vertical channel in fluid communication with the inside of the enclosed membrane module.
  • the enclosure system is modular, and where a plurality of enclosed membrane modules can be stacked one on top of the other.
  • the lower gas manifold can be purged of liquid that may accumulate as a result of condensation or liquid leakage into the manifold.
  • a high air flow rate is delivered to the lower manifold either by increasing the airflow through the membranes, or by supplemental air supplied directly to the lower manifold, or a combination of both, so as to transport the accumulated liquid to either the airlift system or to the liquid surface.
  • the enclosure system is retrofittable to an existing membrane module.
  • a Membrane-Aerated Biofilm Reactor of the type comprising: a frame and having an upper and lower headspace; an array of membranes disposed within the frame and extending between the upper headspace to the lower headspace; characterised in that the MABR further comprises an enclosure system as described above.
  • the air injection port is between 0.5 m to 3 m below the liquid surface within the modular collar of the framing system.
  • the air injection port is 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.7, 1.8, 1.9, 2., 2.1, 2.2, 2.3, 2.4, 2.5, 2.6, 2.7, 2.8, 2.9, or 3.0 m below the liquid surface within the modular collar of the framing system.
  • the air injection port is less than 2.5 m below the liquid surface within the modular collar of the framing system, that is, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.7, 1.8, 1.9, 2., 2.1, 2.2, 2.3, 2.4, or 2.5 m below the liquid surface within the modular collar of the framing system.
  • an enclosure system for use with a membrane module in membrane supported biofilm reactors, the membrane module of the type having an upper and lower headspace separated by an array of gas-permeable hollow fibre membrane cassettes secured in parallel in the module, wherein the cassettes are a linear arrangement of potted hollow fibre membranes, comprising an upper and lower manifold into which are potted a large number of hollow fibre membranes or a number of bunches of hollow fibre membranes, characterised in that the enclosure system comprises:
  • a low-pressure airlift mixing system which is integrated into at least one panel of said plurality of panels, which is configured to transport liquid either from inside the membrane module to outside of the membrane module, or vice versa, so that liquid is pumped in an upward or downward direction through the enclosed membrane module, to encourage good liquid flow through the enclosed membrane module when it is installed in a bioreactor tank, wherein the airlift mixing system comprises:
  • an airlift channel and a first downcomer which are in fluid communication with each other at their bottom, forming two vertical channels of a substantially U-shaped tube which is open at both ends;
  • a vertical return channel having its top in fluid communication with the top of the channel of the substantially U-shaped tube proximal the vertical return channel;
  • an air injection port configured to accept and deliver air into the base of the airlift channel to induce upward flow of liquid above the air injection port in the airlift channel, causing a corresponding downward flow of liquid in the first downcomer;
  • the airlift mixing system further comprises a third vertical channel, giving the airlift mixing system a substantially W-shape, wherein the third vertical channel is a second downcomer, and wherein one of the vertical channels is the air-lift channel, which is in fluid communication with the first and second downcomer.
  • the vertical return channel is open to the environment outside of the enclosed membrane module and configured to provide a continuous channel to supply liquid from one location within the bioreactor or tank, or another holding tank or compartment within a treatment system.
  • the first downcomer is in fluid communication with liquid outside the enclosed membrane module and the airlift channel is in fluid communication with liquid inside of the enclosed membrane module.
  • the first and second downcomer is in fluid communication with liquid outside the enclosed membrane module and the airlift channel is in fluid communication with liquid inside of the enclosed membrane module.
  • the air that is supplied to the airlift channel is sourced from either exhaust air from the membranes, supplemental air from an external source, or both.
  • the air injection port is configured to release air continuously, in a pulsed or periodic manner, or a combination of both.
  • the air injection port is connected to an air syphon configured to allow air to accumulate and be released periodically to the air injection port.
  • the air injection port is configured to introduce air axially, radially, both axially and radially, or at an angle so as to induce turbulent liquid flow within the airlift channel.
  • the air injection port is 3.0 m or less below the liquid surface within the modular collar of the enclosure system.
  • the airlift mixing system is configured to control the level of liquid within the enclosed membrane module relative to the level of liquid outside the enclosed membrane module.
  • at least one of the panels in a four-sided enclosed membrane module are configured to each accommodate the airlift mixing system.
  • at least two, three or all panels in a four-sided enclosed membrane module are each configured to accommodate the airlift mixing system.
  • the system further comprises a liquid flow distribution means in the headspace of the enclosed membrane module configured to provide uniform liquid flow through the enclosed membrane module.
  • the enclosure system is modular, and where a plurality of enclosed membrane modules can be stacked one on top of the other.
  • the lower gas manifold can be purged of liquid, such as water, that may accumulate as a result of condensation or leakage.
  • a high air flow rate is delivered to the lower manifold either by increasing the airflow through the membranes, or by supplemental air supplied directly to the lower manifold, or a combination of both, so as to transport the accumulated liquid to either the airlift mixing system or to the liquid surface.
  • the enclosure system is retrofittable to an existing membrane module.
  • a membrane aeration module of the type comprising: a frame and an upper and lower headspace separated by an array of gas- permeable hollow fibre membrane cassettes fitted in parallel in the fame in the membrane aeration module, wherein the cassettes are in a linear arrangement of potted hollow fibre membranes, comprising an upper and lower manifold into which are potted a large number of hollow fibre membranes or a number of bunches of hollow fibre membranes.
  • the term "Membrane Aerated Biofilm Reactor (MABR)” should be understood to mean a Membrane Supported Biofilm Reactor (MSBR) for treating wastewater liquids to remove carbonaceous pollutant removal, nitrify/denitrify the pollutants, and/or perform xenobiotic biotreatment of the wastewater constituents. Soluble organic compounds in the liquid are supplied to the biofilm from the biofilm- liquid interface, whereas gas supply to the biofilm is from the biofilm- membrane interface (by diffusing through the membrane).
  • a biofilm consisting of a heterogeneous population of bacteria (generally including nitrifying, denitrifying, and heterotrophic, bacteria) grows on the fluid phase side of the membrane.
  • MABRs can achieve bubble- less aeration and high oxygen utilization efficiency (up to 100%) and the biofilm can be separated into aerobic/anoxic/anaerobic zones to simultaneously achieve removal of carbonaceous organic pollutants, as well as nitrification and denitrification in a single biofilm.
  • An example of MABRs of the type comprising a lumen containing a gas phase, a liquid phase, and a gas permeable membrane providing an interface between the gas and liquid phases are described by European Patent No. 2 361 367 (University College Dublin).
  • upper headspace should be understood to mean an enclosed upper membrane-free zone above the membrane cassettes
  • lower headspace should be understood to mean a lower membrane-free zone below the membrane cassettes and in fluid communication with the water in a tank.
  • the term "bunch of membranes” should be understood to mean a collection of from 10 to 100,000, 10 to 10,000, 10 to 1,000 or 10 to 100 gas-permeable, hollow membrane fibres, which are potted at either end into a circular bunch or a shaped element such that the ends of the fibres are open.
  • the membranes can be arranged vertically in the MABR, in which case the resulting liquid flow would be parallel to the membranes, or the membranes could be arranged horizontally in the MABR, resulting in a cross-flow configuration.
  • shaped element or "shaped connector” should be understood to mean an element which gives the bunch of membranes a particular shape (e.g. chevron shaped, cross-shaped, linear, square, rectangular, triangular, hexagonal, other polygonal or circular cross-section etc.). This provides a connector end that can be glued into, or otherwise secured in a gas-tight manner to, the upper or lower manifolds, which then become known as potted membranes.
  • upper manifold and “lower manifold” should be understood to mean gas manifolds which are equipped with ports designed to receive the shaped element connectors, which are attached to each end of the bunches of membranes.
  • bunches of membranes may be potted directly into the upper and lower gas manifolds to form a continuous bunch of membranes stretching from one end of the manifold to the other (see Figure IB).
  • the top manifold is referred to as the upper manifold and the bottom manifold is referred to as the lower manifold.
  • the upper and lower manifolds are in fluid communication with the internal architecture of all the hollow fibres such that air/gas can flow from the inside of the upper manifold, through the hollow fibres to the lower manifold, or vice versa.
  • the term "cassette” should be understood to mean a linear arrangement of potted hollow fibre membranes, comprising an upper and lower manifold into which are potted a large number of hollow fibre membranes or a number of bunches of hollow fibre membranes.
  • a cassette is illustrated in Figures 1A and IB. If gas is supplied to the upper manifold, then this manifold serves as the inlet manifold and the gas will flow downwards within the hollow fibres and into the lower manifold, which will serve as the exhaust gas manifold.
  • membrane module or “Membrane Aerated Biofilm Reactor (MABR)” should be understood to mean a device into which a number (2-1,000, 2-900, 2-800, 2-750, 2-700, 2-650, 2-600, 2-550, 2-500, 2-450, 2-400, 2-350, 2-300, 2- 250, 2-200, 2-150, 2-100, 2-50) of cassettes consisting of hollow fibre membranes can be secured in parallel.
  • the cassettes are generally secured in a frame.
  • the term "frame” in the context of use with a membrane module should be understood to mean a housing that is capable of receiving 2-1,000, 2-900, 2- 800, 2-750, 2-700, 2-650, 2-600, 2-55, 2-500, 2-450, 2-400, 2-350, 2-300, 2-250, 2-200, 2-150, 2-100, 2-50 cassettes and hold them in parallel with a well-defined and even spacing between adjacent cassettes.
  • 2-200 cassettes are typically arranged within a frame.
  • a frame is illustrated in Figure 1C.
  • the term “enclosed membrane module” should be understood to mean a membrane module which is open at the top and bottom but which is encased with an enclosure system as illustrated in Figure 2.
  • the term "enclosure system” or “modular enclosure system” should be understood to mean a series of panels that can be attached to the frame of a membrane module (see Figure 2) or can be arranged to form an enclosed frame for a membrane module.
  • the panels of the enclosure system may incorporate enclosed channels, or conduits for water flow. When water is encouraged to flow through these channels or conduits, they induce a vertical water velocity past the membranes in the enclosed membrane module.
  • the enclosure can be modular in nature and designed to permit the stacking of enclosed membrane modules to form a continuous enclosed volume consisting of several levels of membrane cassettes.
  • the panels may also extend vertically above the upper manifold and extending beyond the surface of the water within the system. This arrangement separates the water inside the enclosed membrane module from the water outside of the enclosed membrane module.
  • enclosed channel should be understood to mean a fully enclosed conduit or pipe that is either moulded to or attached to the panels forming the enclosure of the invention.
  • the enclosed channel may have a square, rectangular, triangular, hexagonal, other polygonal or circular cross-section.
  • module collar should be understood to mean a tightly fitted enclosure that extends the height of the panels of the enclosed membrane module (encased by the enclosure of the invention) vertically by 100 mm to 500 mm above, and preferably 100 mm- 1000 mm above the upper manifold and extending beyond the surface of the liquid. It separates the liquid inside the enclosed membrane module from the liquid outside of the enclosed membrane module.
  • downcomer should be understood to mean a vertical, enclosed channel that is moulded into, or attached to, a panel of the enclosed membrane module. The top of this downcomer is located beneath the surface of the liquid, and liquid within the downcomer flows in a downwards direction.
  • airlift channel should be understood to mean a vertical enclosed channel that is normally filled with liquid, installed below the surface of the liquid, such as wastewater, or protruding above the surface of the liquid. Air is introduced continuously, or in a pulsatile fashion, through the walls of a vertical, enclosed channel at a point that is approximately 0.5 m to 3 m below the liquid (wastewater) surface level in the bioreactor. The rising bubbles, formed and released within the enclosed channel rise and encourage an upwards flow of liquid (wastewater) within the enclosed channel.
  • the air may be injected into the airlift channel using a variety of injection methods including: radial, axial, dual radial and axial, and swirl, under both steady and pulsating injection modes.
  • Pulsatile air injection may be affected by either stopping and starting the air flow, either by means of solenoid valves or by the use of an air syphon.
  • the design of a pulsatile air injection method using an air syphon is described in detail in US Patent 6,162,020.
  • substantially U-shaped tube should be understood to mean two vertically aligned enclosed channels, fabricated into, or attached to a sidewall of the enclosure system: one channel being a downcomer and one channel being an airlift channel.
  • the two vertical channels are connected by a U-bend, or a substantially U- shaped bend connector, at the base.
  • One of the upper ends of the substantially U-shaped tube is open towards the enclosed module (within the modular collar and usually the downcomer, but it can also be the airlift channel) and the other upper end of the substantially U-shaped tube is open to the area outside of the modular collar (usually the airlift channel, but it can also be the downcomer).
  • substantially W-shaped tube should be understood to mean three vertically aligned enclosed channels, fabricated into, or attached to a sidewall of the enclosure system: two channels being a first and second downcomer and one channel being an airlift channel.
  • the three vertical channels are aligned adjacent to each other and connected by a U-bend, or a substantially U-shaped bend connector, at the base.
  • One of the upper ends of the substantially W-shaped tube is open towards the enclosed module (within the modular collar and is usually considered to be the airlift channel).
  • the other upper ends of the substantially W-shaped tube are open to the area outside of the modular collar (usually considered to be the first and second downcomer channels).
  • the order of the airlift channel and first and second downcomer as they appear in the W-shaped tube can vary according to the user's preference.
  • airlift pump should be understood to mean a system comprising a substantially U-shaped tube with air being injected into the base of one of the vertical channels of the substantially U-shaped tube to induce a flow of liquid through the substantially U-shaped tube.
  • the rising air bubbles will induce an upwards flow of liquid above the point of air injection in the airlift channel, causing a corresponding downflow of liquid in the other vertical channel of the substantially U-shaped tube (the first downcomer).
  • a similar arrangement can be made for a system having a substantially W-shaped tube, with air being injected into the base of one of the vertical channels of the substantially W-shaped tube to induce a flow of liquid through the substantially W-shaped tube.
  • air syphon should be understood to mean a syphon of the type described in US Patent 6,162,020 which incorporates an air reservoir that is filled continuously with air but which discharges the air to an injection port in the airlift channel periodically when the volume of air is sufficient to create a syphon.
  • vertical return channel should be understood to mean a continuous channel from the top of an enclosed membrane module to the base of the enclosed membrane module, or to the base of the lowest enclosed membrane module if the modules are stacked.
  • the vertical return channel allows liquid to flow between the top of the enclosed membrane module to the base of the tank in which the modules are installed. The direction of flow will depend upon the operating mode of the airlift pump. Alternatively, it allows treated liquid from the top of the enclosed membrane module to be pumped to the bottom of the tank through the airlift pump.
  • tank holding tank
  • biological reactor biologically treated water or wastewater
  • MABR Membrane Aerated Biofilm Reactor
  • liquid should be understood to mean “water” or “wastewater”, which should be understood to mean any water that has been adversely affected in quality by anthropogenic influence.
  • Wastewater can originate from a combination of domestic (for example, sewage), industrial, commercial or agricultural activities, surface runoff or storm-water, and from sewer inflow or infiltration.
  • Figure 1A illustrates a cassette of the prior art comprising shaped elements with individual bundles of fibres
  • Figure IB illustrates a cassette of the prior art in which the membranes are potted continuously directly into the upper and lower manifolds and which require no shaped element connectors
  • Figure 1C illustrates an elevation view of the membrane cassettes within a metal frame of the prior art that form a membrane module.
  • Figure 2A illustrates a side elevation view of an enclosed membrane module of the present invention
  • Figure 2B illustrates a side elevation view of the enclosed membrane module of the present invention, showing an integrated airlift system comprising an airlift pump, a first downcomer and a return channel.
  • These membrane modules are completely surrounded and protected by the enclosure's panels, but are open at the top and the bottom.
  • Figure 2C illustrates a plan view of an enclosed membrane module of present invention.
  • Figure 3A illustrates a side elevation of an enclosed membrane module of the present invention, which has been fitted with a modular collar and installed in a holding tank or bioreactor (not shown).
  • Figure 3B shows that if the liquid (water) level within the modular collar is higher than the surrounding liquid (water) level in the tank, the direction of flow is reversed when compared to the direction of flow in Figure 3A.
  • Figure 4A and Figure 4B illustrate how the airlift mixing system provided on a panel of the enclosure system of the invention that can operate as an airlift pump.
  • the airlift mixing system is capable of providing a flow from the upper headspace to the tank or a flow from the tank to the upper headspace, thus inducing an upward or a downward liquid flow, respectively, within the enclosed membrane module of the present invention.
  • the intake port of the airlift mixing system is located within the modular collar and draws liquid from within the enclosed membrane module.
  • the airlift channel discharges liquid outside of the modular collar and liquid may flow downwards through the return channel to the base of the tank within which the entire enclosed membrane module is located.
  • the air injection port is located in the enclosed channel of the other side of the U-shaped tube that forms the airlift mixing system (now the upward flowing channel), and the discharge point of the airlift channel is now located within the modular collar and delivers liquid to the upper headspace above the membranes thus creating a higher liquid level within the enclosed module and forcing a downward velocity of liquid.
  • the liquid within the tank is now drawn up from the bottom of the tank through the return channel or in via opening at point 12.
  • the intake port of the first downcomer and return channel is now located outside of enclosed membrane module.
  • Figure 5A and Figure 5B show a plan view and side elevation view of the modular collar that is attached to the top of the enclosed membrane module of the present invention or to the top of the uppermost membrane module in a stack.
  • Figure 6A and Figure 6B illustrate how the enclosed membrane modules of the present invention may be stacked within a tank.
  • Figure 6A and Figure 6B are operating in the modes shown in Figures 4A and 4B respectively.
  • FIG. 7A and Figure 7B illustrate a plan view and side view in cross section of four membrane modules each enclosed by a framing system of the present invention and which are installed in a tank.
  • the whole treatment system makes up Membrane Aerated Biofilm Reactor which treats inlet wastewater and discharges a treated effluent.
  • Figure 8 illustrates an enclosed membrane module with a liquid flow distribution means in situ in the upper headspace 104 of the enclosed membrane module.
  • Figure 9A and 9B illustrate a side and front view of an airlift mixing system of the present invention, wherein the airlift mixing system is a substantially W-shape.
  • Figure 9C illustrates the substantially W-shaped airlift mixing system in an enclosed membrane module of the present invention.
  • the invention described herein provides low shear conditions, and the effective delivery of substrates to the biofilms growing on membranes, by providing a low pressure, airlift mixing system, which is integrated into a membrane module enclosed by the enclosure system of the invention and that surrounds the membranes.
  • airlift channels are feasible if the pressure against which the water must be pumped is less than about 300 mm of water. Pressure drops of more than 300 mm of water reduce the efficiency of airlift pumping and the water flow rate drops dramatically. For this reason, it is important that the head losses and pressure drops within the airlift mixing system itself are minimized.
  • the size of the pipes or channels used for the airlift mixing system must be selected to minimize pressure losses and maximize airflow rates.
  • the flow rate of liquid that can be achieved in an airlift mixing system is a function of the air flow rate, the depth of the air injection port and the size (effective diameter) of the airlift channel.
  • the liquid flow rate increases with air flow rate and the depth of the air injection port. Since energy consumption is a major environmental concern and operating cost associated with wastewater treatment, it is important to minimize the energy requirements for mixing and aeration. This can be accomplished by using the air supplied to the membranes for both oxygen transfer and mixing. Also, by using an airlift mixing system with a shallow depth for the air injection port, the air pressure required within the membranes can be kept low and energy consumption can be minimized.
  • the liquid flow rate through an enclosed membrane module can thus be controlled by the design and operating conditions of the airlift mixing system, while the operating air pressure is independent of the depth of submergence of the membranes in stacked membrane modules and only dependant on the depth of the air injection into the airlift mixing system.
  • Figure 1 illustrates a cassette 100 comprising shaped element connectors 101 with individual bundles of fibres 102, potted into upper 98 and lower 99 manifolds
  • Figure IB illustrates a cassette 100 in which the membrane fibres 102 are potted continuously and directly into the upper 98 and lower 99 manifolds and which require no shaped element connectors 101
  • Figure 1C illustrates a view of membrane cassettes 100, being assembled into a membrane module 120 of the prior art.
  • the membrane module 120 comprises a frame 110 into which the cassettes 100 can be fitted.
  • Figure 2A illustrates a side elevation view of a membrane module enclosed by the enclosure system of the present invention to form an enclosed membrane module, with the enclosed membrane module generally referred to by reference numeral 1.
  • the enclosed membrane module 1 comprises panels 3a,3b,3c,3d which enclose the membrane module 120, and comprise an airlift mixing system 4 (see Figure 2B).
  • the panels 3a,3b,3c,3d of the enclosed membrane module 1 completely surround and encloses the cassettes 100, but the enclosed membrane module 1 is open at the top and the bottom.
  • Figure 2B illustrates a side elevation view of the enclosed membrane module 1, showing the airlift mixing system 4.
  • the airlift mixing system 4 is integrated within the panels 3a,3c.
  • the airlift mixing system 4 could also be integrated within panels 3b, 3d.
  • the airlift mixing system 4 comprises a series of enclosed tubes that form a substantially U-shaped tube 5 with a vertical tube attached thereto.
  • the substantially U- shaped tube 5 comprises a first downcomer 6 connected to an airlift channel 7 by a u- bend 8.
  • the system may comprise a return channel 9.
  • the enclosed membrane module 1 is shown to further comprise a reinforcing bar 10 and ports 11,12.
  • the reinforcing bar 10 extends from panel 3a to the opposite panel 3c.
  • a modular collar 20 is attached to the top of the enclosed membrane module 1, and is configured to separate the ports 11 and 12.
  • the port 12 When water is flowing from an upper headspace 104 to a lower headspace 106, the port 12 provides fluid communication between liquid in the tank and the upper headspace 104 through the substantially U-shaped tube 5. When liquid is flowing from the lower headspace 106 (or from the bottom of a holding tank) to the upper headspace 104, the port 11 provides fluid communication between the upper headspace and the liquid in the bulk tank through the substantially U-shaped tube 5. The port 12 allows for air injected into the airlift channel 7 to escape to atmosphere, and not to become entrained in the liquid flowing downward in the return channel 9 to the bottom of the tank.
  • Figure 2C illustrates a plan view of an enclosed membrane module 1. As illustrated, the upper headspace 104 of the enclosed membrane module 1 and a series of parallel membrane cassettes 100 are visible. The cassettes 100 are arranged in parallel that provide space between each cassette 100 to allow liquid to flow there between.
  • Figure 3A illustrates a side elevation of an enclosed membrane module 1, which has been fitted with the modular collar 20 and installed in a holding tank or bioreactor 200.
  • the level of liquid inside the modular collar 20 is below the liquid level in the surrounding tank 200, liquid will flow upwards through the enclosed membrane module 1 to equalize the water levels inside and outside of the tank 200.
  • the greater the difference in liquid level between the outside and inside of the modular collar 20 (h mm of liquid as shown in Figure 3A), the greater the induced liquid velocity through the enclosed membrane module 1.
  • Figure 3B shows that if the liquid level within the modular collar 20 is higher than the surrounding liquid level in the tank 200, the direction of flow is reversed. Again, the greater the difference in liquid levels (h), the greater the liquid velocity created within the enclosed membrane module.
  • the arrows in Figure 3A and 3B illustrate the direction of liquid flow induced by the changes in levels of liquid within the membrane module 120 and the tank 200.
  • Figure 4A and Figure 4B illustrates the detail of the airlift mixing system 4 within a panel 3a,3b,3c,3d that can operate as an airlift pump, and which is capable of providing either an upward or a downward liquid flow respectively within the enclosed membrane module 1.
  • the airlift mixing system 4 comprises the enclosed substantially U-shaped tube 5 connected to the vertical return channel 9 at one side thereof.
  • Figure 4A the configuration of the channels of the airlift mixing system 4 is shown which illustrate movement of liquid from the bottom of the tank 200 to the top of the enclosed membrane module 1.
  • the outer enclosed channel of the airlift mixing system 4 acts as a first downcomer 6, which receives liquid from inside the modular collar 20 (from the upper headspace 104) and acts to reduce the liquid level within the modular collar 20 relative to the liquid level within the tank 200.
  • Air is injected into a middle-enclosed channel, here called the airlift pump 7, via an air injection port 40.
  • the rising bubbles produced by the air injection port 40 induce a vertical liquid velocity flow (indicated by Arrow A), which moves water as illustrated by the arrows shown.
  • Arrow A vertical liquid velocity flow
  • the airlift pump 7 and the return channel 9 merge outside of the enclosed membrane module 1, the air bubbles are vented at the liquid surface and the liquid flows downwards through the return channel 9 to the base of the tank 200.
  • FIG 4B the configuration of the channels of the airlift mixing system 4 is shown which illustrate movement of liquid from the upper manifold 104 within the enclosed membrane module 1 downwards through the cassettes 100 to the bottom of the tank 200.
  • the air injection port 40 is switched to the outer channel of the substantially U-shaped tube 5 and becomes the airlift pump 7, while the inner channel of the substantially U-shaped tube 5 becomes the first downcomer 6 and is physically connected to the return channel 9.
  • the airlift channel 7 supplies liquid to the inside of the modular collar 20 and upper manifold 104, causing an increase in water level above the membrane module 120 relative to the liquid outside of the modular collar 20 in the tank 200. In this operating mode, liquid is drawn from the bottom of the tank 200 via the return channel 9 as illustrated.
  • the arrows A in Figure 4B illustrate the direction of liquid flow induced by the airlift channel 7.
  • the liquid level in the modular collar 20 covering the enclosed membrane module 1 is separated from the liquid outside in the tank 200 in which the module is immersed due to the seal created by the enclosed membrane module 1, such that the airlift mixing system 4 may raise or lower the liquid level covering the membrane module 1 relative to the liquid level in the tank 200.
  • Figure 5A and Figure 5B show a plan view and side elevation view of the modular collar 20 that is attached to the top of the enclosed membrane module 1.
  • the modular collar 20 comprises sides 21a,21b,21c,21d and is configured to fit to a frame 110 of a membrane module 120 or to the top of an enclosed membrane module 1, thus providing an upper headspace 104 with an increased height when compared to upper headspace 104 without a modular collar 20 in place.
  • the modular collar 20 is configured to separate the ports 11 and 12.
  • Figure 6A and Figure 6B illustrate how a number of enclosed membrane modules ⁇ , ⁇ may be stacked one upon the other within a tank 200.
  • the stacked enclosed membrane modules ⁇ , ⁇ are configured such that the return channel 9 of module 1 connects to the return channel 9 of the module ⁇ .
  • Figure 6A and Figure 6B are operating in the modes shown in Figures 4A and 4B, respectively.
  • the substantially U-shaped tube 5 of module ⁇ is cut off by the insertion of a baffle 22 and remains unused.
  • the liquid level outside the modular collar 20 of the enclosed membrane module 1 is higher than the liquid level inside the modular collar 20, thus creating an upward velocity of liquid from the bottom of the tank 200 to the upper headspace 104 of the enclosed membrane module 1.
  • the liquid level outside the modular collar 20 of the membrane module 1 is lower than the liquid level inside the modular collar 20, thus creating a downward velocity of liquid from the upper headspace 104 of the enclosed membrane module 1 to the bottom of the tank 200.
  • FIG. 7A and Figure 7B illustrate a plan view and side view in cross section of four enclosed membrane modules 1, which are installed in a tank 200 to form a treatment system 300.
  • the whole treatment system 300 makes up a MABR, which treats inlet wastewater and discharges a treated effluent.
  • the treatment system 300 comprises the tank 200 having a housing 201 and a series of stacked enclosed membrane modules 1.
  • the liquid level outside the modular collar 20 in the tank 200 is lower than the liquid level inside the modular collar 20 (indicated by the h mm), thus creating a downward velocity of liquid from the upper manifold 104 of the enclosed membrane module 1 to the bottom of the tank 200.
  • liquid water or wastewater (effluent) enters the system 300 via an inlet waste pipe A and the treated effluent exits the system 300 via outlet B.
  • the liquid is treated by interacting with the cassettes 100 of the enclosed membrane modules 1.
  • the airlift mixing system 4 provides a low-pressure, low-energy mixing system that ensures there is effective contact between as much of the membrane- attached pollutant-degrading biofilm that accumulates on the membranes 102 and the pollutant-rich wastewater to be treated.
  • the enclosed membrane module 1 is designed to operate with gas pressures inside the hollow membrane fibres 102 which may be higher or lower than the external hydrostatic pressure of the tank 200.
  • the enclosed membrane module 1 is illustrated with a liquid flow distribution means 60 is shown in situ in the upper headspace 104 of the enclosed membrane module 1.
  • the water flow distribution means 60 is in fluid communication with port 12 and is configured to ensure uniform flow through the enclosed membrane module 1, that is the velocity of the flow of liquid within the module is equal on a horizontal plane.
  • the provision of a uniform liquid flow through the enclosed membrane module 1 ensures an even upflow liquid velocity throughout the membrane module 1 and prevents short circuiting of the liquid between the port 12 and bottom of the return channel 9.
  • the uniform velocity ensures that all of the membrane supported biofilm is contacted by the wastewater and removes the creation of a dead zone or poorly mixed regions where no flow occurs.
  • the airlift mixing system 4 is shown to contain a second downcomer 6a giving the airlift mixing system 4 a substantially W-shape, where the central vertical channel is the air-lift channel 7 in fluid communication with the first downcomer 6 and second downcomer 6a on either side thereof.
  • the air is delivered into the central airlift channel 7 at the air injection port 40, while the vertical channels, the first and second downcomer 6,6a, are connected to the air lift channel 7 by a common water manifold 8a along the bottom, thus forming a substantially W-shape tube 50. Due to the water and air mixture flowing upwards through the central vertical channel 7, a downward waterflow is induced in both the first and second downcomer 6,6a.
  • the liquid discharged through the port 11 and the flow distribution means 60, originating from the airlift channel 7, must flow vertically downward and out of the enclosed membrane module 1 through the open bottom.
  • One of the advantages of the W- shaped mixing system is that there are two inlets to the downcomers in this configuration and liquid can be introduced into the W-Shaped mixing system from two different points in tank. In the preferred configuration if the flow of liquid in the W-shaped tube is to be reversed, then air must be introduced into both vertical channels either side of the central vertical channel to make sure both of the side vertical channels become airlift channels and the central vertical channel becomes the downcomer.
  • the W-shaped airlift mixing system can also be stacked as shown in Figure 6A and Figure 6B, one or two vertical return channels can also be installed on either side of the W-shaped mixing system.
  • the W-shaped mixing system is easy to retrofit to existing modules, and can provide for larger area for flow using vertical channels with a smaller cross section.
  • the enclosed membrane module both protects the membranes from damage during transit and incorporates a low-pressure airlift system to encourage good liquid flow through the membrane module when the modules are installed in a bioreactor.
  • Such independent control allows successful installation in tanks of varying depth and shape or which were previously designed for different purposes, e.g. settling tanks, can be upgraded to incorporate the MABR without the need for an installation of an independent mixing system.

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  • Chemical & Material Sciences (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Biodiversity & Conservation Biology (AREA)
  • Microbiology (AREA)
  • Hydrology & Water Resources (AREA)
  • Engineering & Computer Science (AREA)
  • Environmental & Geological Engineering (AREA)
  • Water Supply & Treatment (AREA)
  • Organic Chemistry (AREA)
  • Separation Using Semi-Permeable Membranes (AREA)

Abstract

L'invention concerne la conception d'une enveloppe pour un module d'aération à membrane, qui incorpore une pompe à émulsion d'air réversible à basse pression pour favoriser un écoulement d'eau vertical à travers et entre les membranes dans le module. Les modules à membrane enveloppés sont appropriés pour être utilisés dans des réacteurs à biofilm aéré à membrane, qui sont utilisés pour traiter de l'eau ou des eaux usées.
PCT/EP2018/054181 2017-02-20 2018-02-20 Système de mélange à émulsion d'air réversible à basse pression destiné à être utilisé avec un réacteur à biofilm aéré à membrane WO2018150055A1 (fr)

Priority Applications (9)

Application Number Priority Date Filing Date Title
PL18709946T PL3582883T3 (pl) 2017-02-20 2018-02-20 System obudowy do stosowania z modułem membranowym reaktora z warstwą biofilmu napowietrzanego membranowo i zawierający niskociśnieniowy system mieszający powietrznego podnośnika cieczy
CN201880012853.3A CN110461448B (zh) 2017-02-20 2018-02-20 与膜曝气生物薄膜反应器一起使用的低压可逆气升混合系统
JP2019565982A JP7011671B2 (ja) 2017-02-20 2018-02-20 メンブレンエアレーション型バイオフィルムリアクタと共に使用するための低圧可逆エアリフト混合システム
CA3052371A CA3052371A1 (fr) 2017-02-20 2018-02-20 Systeme de melange a emulsion d'air reversible a basse pression destine a etre utilise avec un reacteur a biofilm aere a membrane
EP18709946.0A EP3582883B1 (fr) 2017-02-20 2018-02-20 Système pour contenir un module membranaire d'un réacteur à biofilm à membrane aérée comprenant un système de mélange de type airlift à basse pression.
ES18709946T ES2884099T3 (es) 2017-02-20 2018-02-20 Sistema de contención para usarse con un módulo de membrana de un reactor de biopelícula aireada por membrana y que comprende un sistema de mezcla de elevación de aire de baja presión
BR112019017266A BR112019017266A2 (pt) 2017-02-20 2018-02-20 sistema de invólucro para uso com um módulo de membrana do tipo que tem um espaço vazio superior e inferior separados por uma matriz de membranas de fibra oca permeáveis a gás e um módulo de aeração por membrana
US16/487,281 US11434155B2 (en) 2017-02-20 2018-02-20 Low-pressure, reversible airlift mixing system for use with a membrane aerated biofilm reactor
DK18709946.0T DK3582883T3 (da) 2017-02-20 2018-02-20 Indkapslingssystem til anvendelse med et membranmodul af en membranbeluftet biofilmsreaktor og omfattende et lavtryks-lufttransport-blandingssystem

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
US201762461139P 2017-02-20 2017-02-20
EP17156862.9 2017-02-20
US62/461,139 2017-02-20
EP17156862 2017-02-20

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CN109095609A (zh) * 2018-09-07 2018-12-28 天津海之凰科技有限公司 一种立式密闭型ehbr污水处理装置及方法
CN111018099A (zh) * 2019-12-12 2020-04-17 哈尔滨工业大学(深圳) 一种壳体以及膜生物膜反应器
JP2021000607A (ja) * 2019-06-21 2021-01-07 栗田工業株式会社 生物処理装置の運転方法

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CN109095609A (zh) * 2018-09-07 2018-12-28 天津海之凰科技有限公司 一种立式密闭型ehbr污水处理装置及方法
JP2021000607A (ja) * 2019-06-21 2021-01-07 栗田工業株式会社 生物処理装置の運転方法
JP7283253B2 (ja) 2019-06-21 2023-05-30 栗田工業株式会社 生物処理装置の運転方法
CN111018099A (zh) * 2019-12-12 2020-04-17 哈尔滨工业大学(深圳) 一种壳体以及膜生物膜反应器
CN111018099B (zh) * 2019-12-12 2024-05-07 哈尔滨工业大学(深圳) 一种壳体以及膜生物膜反应器

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