US20150191382A1

US20150191382A1 - Systems and methods for waste treatment

Info

Publication number: US20150191382A1
Application number: US14/412,973
Authority: US
Inventors: Remy BLANC; Ehud LESHEM
Original assignee: AQUANOS ENERGY Ltd
Current assignee: AQUANOS ENERGY Ltd
Priority date: 2012-07-19
Filing date: 2013-07-17
Publication date: 2015-07-09
Also published as: CN104540785B; US9790112B2; EP2874955A1; IN2015DN00386A; US20140042085A1; WO2014013494A1; CN104540785A

Abstract

Systems and methods for aerobically processing waste, in which an aerobic bioreactor is in selective fluid communication with a source of oxygen-rich liquid medium. The aerobic bioreactor is configured for aerobically processing waste via bacteria fixed on media to provide processed effluent from the waste. The source of oxygen-rich liquid medium is different from the aerobic bioreactor.

Description

TECHNOLOGICAL FIELD

The presently disclosed subject matter relates to methods and systems for waste treatment, in particular for waste water treatment.

PRIOR ART

References considered to be relevant as background to the presently disclosed subject matter are listed below:

U.S. Pat. No. 6,896,804
U.S. Pat. No. 4,005,546
U.S. Pat. No. 4,209,388
U.S. Pat. No. 3,955,318
US 2010/288695A
JP 63252596A
US 2011/151547A
US 2003/209489A
JP 3198727A
JP 61197098A
JP 58166989A
FR 2344627A
CN 2018014190
CN 101853955A
WO 11022754A
US 2010/300962A
CN 101560484A
JP 2008272721A
US 2010/018918
CN 102211834
Gonzalez C. Marciniak J, Viliaverde S, León C, García P A, Muñoz R., Water Science and Technology, 58; 92-105; 2008.
Muñoz R, Guieysse B., Water Research, 40; 2799-2815 2006

Acknowledgement of the above references herein is not to be inferred as meaning that these are in any way relevant to the patentability of the presently disclosed subject matter.

BACKGROUND

The desirability of treating waste particularly in liquid form, also referred to herein interchangeably as wastewater, is well known. Some types of waste treatment are conventionally based on biological oxidation of the organic matter in the waste to carbon dioxide (CO₂), using microorganisms such as bacteria. Many such waste treatment processes occur in the presence of oxygen, referred to as aerobic processes.
By way of non-limiting example, U.S. Pat. No. 6,896,804 discloses a system and a method for aerobic treatment of waste, including the continual introduction of microalgae.
Also by way of non-limiting example: U.S. Pat. No. 4,005,546 discloses a method of waste treatment and algae recovery; U.S. Pat. No. 4,209,388 discloses a method for the treatment of sanitary sewage comprising water containing suspended or dissolved organic matter, the concentration of which is measured by biochemical oxygen demand (BOD); U.S. Pat. No. 3,955,318 discloses a method of producing an algae product and of purifying aqueous organic waste material to provide clean water.

GENERAL DESCRIPTION

According to a first aspect of the presently disclosed subject matter, there is provided a system for aerobically processing waste, in particular liquid waste, for example waste water, comprising:

- an aerobic bioreactor configured for aerobically processing the waste via bacteria fixed on media to provide processed effluent from the waste;
- a source of oxygen-rich liquid medium, said source being different from and/or separate from said aerobic bioreactor, said source being in selective fluid communication with said aerobic bioreactor.

The system can comprise a recirculation circuit configured for controllably recirculating said liquid medium between said aerobic bioreactor and said source.
Additionally or alternatively, said system is configured for preventing the media from being transferred from the aerobic bioreactor to said source.
Additionally or alternatively, said media is restricted to a confined volume within said aerobic bioreactor.
Additionally or alternatively, in operation of the system a flow of said oxygen-rich liquid medium is forced through (i.e., into and out of) said confined volume wherein to interact with said bacteria.
According to a second aspect of the presently disclosed subject matter, there is provided a system for aerobically processing waste, comprising:

- an aerobic bioreactor configured for aerobically processing waste to provide processed effluent from the waste;
- a source of oxygen-rich liquid medium, said source being different from and/or separate from the bioreactor,
- a recirculation circuit configured for controllably recirculating said liquid medium between said aerobic bioreactor and said source.

The aerobic bioreactor can be configured for aerobically processing waste via bacteria fixed on media, and optionally said system can be configured for preventing the media from being transferred from the aerobic bioreactor to the source. Additionally or alternatively, said media is restricted to a confined volume within said aerobic bioreactor. In operation of the system a flow of said oxygen-rich liquid medium is forced through (i.e., into and out of) said confined volume wherein to interact with said bacteria.
According to a third aspect of the presently disclosed subject matter, there is provided a system for aerobically processing waste, comprising:

- bacteria for aerobically processing waste to provide processed effluent from the waste, said bacteria being fixed on media restricted to a confined volume;
- a flow of oxygen-rich liquid medium forced through (i.e., into and out of) said confined volume wherein to interact with said bacteria.

Said confined volume is provided in an aerobic bioreactor, and a source of oxygen-rich liquid medium provides said flow of oxygen-rich medium, said source being different from and/or separate from the aerobic bioreactor.
Additionally or alternatively, said system is configured for preventing the media from being transferred from the aerobic bioreactor to the source.
Additionally or alternatively, the system comprises a recirculation circuit configured for controllably recirculating said liquid medium between said aerobic bioreactor and said source.
In the system according to any one of the aforementioned first, second and third aspects of the presently disclosed subject matter, said source comprises photosynthetic microorganisms that generate oxygen to said liquid medium responsive to exposure to light.
Additionally or alternatively, said source comprises any one of photosynthetic eukaryotic microorganisms and photosynthetic prokaryotic microorganisms that generate oxygen to said liquid medium responsive to exposure to light.
Additionally or alternatively, said source comprises algae that generate oxygen to said liquid medium responsive to exposure to light.
For example, said photosynthetic microorganisms comprise at least one of: Chlorella spp, spirulina, scendesmus, or any other type of photosynthetic microalgae or cyanobacteria.
Additionally or alternatively, said source comprises a reservoir comprising a channel therein defining a reservoir internal volume, and configured for driving said liquid medium around said channel in operation of the system.
Additionally or alternatively, the system according to any one of the aforementioned first, second and third aspects of the presently disclosed subject matter, further comprises an auxiliary aeration system, configured for selectively providing gaseous oxygen or air to said bioreactor.
Additionally or alternatively, the system according to any one of the aforementioned first, second and third aspects of the presently disclosed subject matter, further comprises an auxiliary CO₂system, configured for selectively providing carbon dioxide to said source.
Additionally or alternatively, said media is fixed in situ within the bioreactor, for example in the form of fixed media. For example the media comprises a substrate that is fixed on one or more sides thereof to the structure of the aerobic bioreactor. For example, such fixed media can be in the form of a plastic matrix attached to the floor or sides of the aerobic bioreactor and/or ropes or fibers hanging within the liquid in the aerobic bioreactor and attached either to the walls or other structure of the aerobic bioreactor or attached to a rigid frame located within the aerobic bioreactor.
Additionally or alternatively, said media is mobile, i.e., free-floating within the bioreactor.
Additionally or alternatively, said media comprise biofilm carrier elements, in the form of solid inert substrates having a relatively large surface area to volume ratio. Such substrates can include, for example, any one of polyethylene or other plastics, and the respective surface area to volume ratio can be, for example, between about 500 m²/m³and about 1300 m²/m³, for example about 650 m²/m³. Alternatively, substrates can include, for example, any one of metallic materials, fibers, cloths, mineral materials (such as for example carbon, volcanic tuff, gravel), and so on, at least some of which can have respective surface area to volume ratios much higher than 1300 m²/m³.
Additionally or alternatively, the system according to any one of the aforementioned first, second and third aspects of the presently disclosed subject matter, further comprises a waste inlet configured for receiving the waste and a dispensing outlet for dispensing treated effluent, and wherein

- said bioreactor comprises at least one vessel defining a respective aerobic processing volume, the at least one vessel comprising a bioreactor fluid medium inlet and a bioreactor fluid medium outlet, each in selective fluid communication with said source, the at least one vessel being configured for ensuring that the respective aerobic processing volume is partially or fully shielded from light at least during operation of the system;
- said source comprises at least one reservoir defining a respective reservoir volume for accommodating a volume of said liquid medium, and further comprising a source fluid medium inlet and a source fluid medium outlet, each in selective fluid communication with said aerobic bioreactor, and a driving device for providing motion to said liquid medium within said respective reservoir volume, the at least one reservoir being configured for ensuring that the respective reservoir volume is exposed to light at least during operation of said source wherein to provide said oxygen-rich liquid medium.

For example, said driving device comprises a powered paddling device mounted to the respective said reservoir. Additionally or alternatively, said at least one reservoir comprises at least one flow channel in the form of a horizontal endless loop. For example, said at least one flow channel has an annular plan form. For example, said at least one flow channel has a raceway configuration. Additionally or alternatively, said source fluid medium outlet is configured for preventing outflow of said media therethrough.
Additionally or alternatively, the system according to any one of the aforementioned first, second and third aspects of the presently disclosed subject matter further comprises:

- at least one set of conduits providing said fluid communication between said at least one said vessel and a respective said reservoir;
- a pumping system, different from said driving device, for providing recirculation of said medium between said at least one vessel and the respective said reservoir through said set of conduits.

For example, one said conduit connects said source fluid medium inlet with said bioreactor fluid medium outlet and wherein another said conduit connects said source fluid medium outlet with said bioreactor fluid medium inlet.
For example, said bioreactor is configured for providing a through-flow of at least the oxygen-rich liquid medium through the bioreactor at a predetermined velocity, wherein said predetermined velocity is sufficient to cause the media therein to expand within the bioreactor and to mix therein with at least the oxygen-rich liquid medium.
According to a fourth aspect of the presently disclosed subject matter, there is provided a method for aerobically processing waste, comprising:

- aerobically reacting waste in an aerobic bioreactor via bacteria fixed on media;
- providing oxygen-rich liquid medium to the bioreactor from an oxygen-rich liquid source, wherein the oxygen-rich liquid source is different from and/or separate from the bioreactor.

For example, the method further comprises controllably recirculating said liquid medium between said aerobic bioreactor and said oxygen-rich source.
Additionally or alternatively, the method comprises preventing the media from being transferred from the aerobic bioreactor to said source.
Additionally or alternatively, said media is restricted to a confined volume within said aerobic bioreactor. For example, a flow of said oxygen-rich liquid medium is forced through said confined volume wherein to interact with said bacteria.
According to a fifth aspect of the presently disclosed subject matter, there is provided a method for aerobically processing waste, comprising:

- aerobically processing waste in an aerobic bioreactor to provide processed effluent from the waste;
- providing oxygen-rich liquid medium to the bioreactor from an oxygen-rich liquid source, wherein the oxygen-rich liquid source is different from and/or separate from the bioreactor,
- controllably recirculating said liquid medium between said aerobic bioreactor and said source.

For example, said aerobic bioreactor is configured for aerobically processing waste via bacteria fixed on media.
For example, the method further comprises preventing the media from being transferred from the aerobic bioreactor to the oxygen-rich liquid source.
Additionally or alternatively, said media is restricted to a confined volume within said aerobic bioreactor. For example, a flow of said oxygen-rich liquid medium is forced through said confined volume wherein to interact with said bacteria.
According to a sixth aspect of the presently disclosed subject matter, there is provided a method for aerobically processing waste, comprising:

- aerobically processing waste with bacteria to provide processed effluent from the waste, said bacteria being fixed on media restricted to a confined volume;
- forcing a flow of oxygen-rich liquid medium through (i.e., into and out of) said confined volume wherein to interact with said bacteria.

For example, said confined volume is provided in an aerobic bioreactor, and wherein a source of oxygen-rich liquid medium provides said flow of oxygen-rich medium, said source being different from the aerobic bioreactor.
For example, the method comprises preventing the media from being transferred from the aerobic bioreactor to the source. Additionally or alternatively, the method comprises controllably recirculating said liquid medium between said aerobic bioreactor and said source.
In the method according to any one of the aforementioned fourth, fifth, and sixth aspects of the presently disclosed subject matter, said liquid medium contains photosynthetic microorganisms that generate and provide oxygen to said liquid medium responsive to exposure to light.
According to a seventh aspect of the presently disclosed subject matter, there is provided a method for aerobically processing waste, comprising:

- reacting waste aerobically with bacteria in a bioreactor volume under conditions configured for inhibiting or reducing growth of photosynthetic microorganisms;
- providing a flow of oxygen-producing photosynthetic microorganisms through the bioreactor volume from a source configured for promoting oxygen production by photosynthetic microorganisms, the source being different from and/or separate from the bioreactor volume, the photosynthetic microorganisms generating and providing oxygen to said liquid medium responsive to exposure to light; and
- preventing at least a majority of the bacteria from exiting the bioreactor with said flow of photosynthetic microorganisms.

According to an eighth aspect of the presently disclosed subject matter, there is provided a method for aerobically processing waste, comprising:

- reacting waste aerobically with bacteria in a bioreactor volume under conditions configured for inhibiting or reducing growth of photosynthetic microorganisms;
- providing a flow of oxygen-rich liquid which optionally contains oxygen-producing photosynthetic microorganisms through the bioreactor volume from a source configured for promoting oxygen production by photosynthetic microorganisms, the source being different from and/or separate from the bioreactor volume, the photosynthetic microorganisms in the liquid medium generating and providing oxygen to said liquid medium responsive to exposure to light; and
- preventing at least a majority of the bacteria from exiting the bioreactor with said flow of liquid that contains photosynthetic microorganisms or that contains oxygen produced by these organisms.

In the method according to any one of the aforementioned fourth, fifth, sixth, seventh and eighth aspects of the presently disclosed subject matter, said photosynthetic microorganisms comprise any one of photosynthetic eukaryotic microorganisms and photosynthetic prokaryotic microorganisms that generate oxygen to said liquid medium responsive to exposure to light. Additionally or alternatively, said source comprises algae that generate oxygen to said liquid medium responsive to exposure to light. Additionally or alternatively, said photosynthetic microorganisms comprise at least one of: Chlorella spp, spirulina, scendesmus, or any other type of micro algae or cyanobacteria.
In the system according to any one of the aforementioned first, second and third aspects of the presently disclosed subject matter, and/or in the method according to any one of the aforementioned fourth, fifth, sixth, seventh or eighth aspects of the presently disclosed subject matter, the waste is aerobically treatable for removing pollutants therefrom. For example, said waste is a liquid waste. For example, said waste comprises waste water. For example, said waste includes organic types of waste. For example, said waste comprises at least one of animal, agricultural, industrial or human waste transported in water or another liquid medium.
In the method according to any one of the aforementioned fourth, fifth, sixth, seventh and eighth aspects of the presently disclosed subject matter, the method can further comprise at least one of:

- selectively providing gaseous oxygen or air to said bioreactor; and
- selectively providing carbon dioxide to said source.

Additionally or alternatively, a portion of said media is fixed in situ within the bioreactor.
Additionally or alternatively, at least a portion of said media is mobile within the bioreactor.
Additionally or alternatively, said media comprise biofilm carrier elements, in the form of solid inert substrates having a relatively large surface area to volume ratio.
Additionally or alternatively, the method comprises:

- partially or fully shielding the respective aerobic processing volume from light;
- ensuring that the respective reservoir volume is exposed to light.

Additionally or alternatively, the step of aerobically reacting waste includes providing a through-flow of at least the oxygen-rich liquid medium through the bioreactor at a predetermined velocity, wherein said predetermined velocity is sufficient to cause the media therein to expand and to mix therein with at least the oxygen-rich liquid medium.
For example, said method is performed in batch mode or said method is performed in continuous flow mode.
According to a ninth aspect of the presently disclosed subject matter, there is provided an aerobic bioreactor configured for aerobically processing waste via bacteria fixed on media that are mobile within the aerobic bioreactor to provide processed effluent from the waste, comprising:

- a reaction vessel having a fluid inlet and a fluid outlet, and a waste inlet, and defining an internal volume;
- said waste inlet being configured for selectively providing waste to said aerobic bioreactor;
- said fluid inlet and said fluid outlet being connectable to a source of oxygen-rich liquid medium, the source being different from said aerobic bioreactor, wherein said source is in selective fluid communication with said aerobic bioreactor via said fluid inlet and said fluid outlet to provide a recirculation circuit configured for controllably recirculating at least the liquid medium between said aerobic bioreactor and the source;
- the reaction vessel being configured for providing, via said recirculation circuit, a through-flow of at least the oxygen-rich liquid medium through said internal volume at a predetermined velocity, wherein said predetermined velocity is sufficient to cause the media to expand within the reaction vessel and mix therein with at least the oxygen-rich liquid medium.

For example, said predetermined velocity is sufficient to provide a fluidized bed effect to the media within said reaction vessel.
In at least a first example, at said predetermined velocity is sufficient to provide upward motion to at least a first proportion of said media having a density greater than that of said liquid medium. For example, said flow velocity within said reaction vessel is in a direction generally opposed to the gravitational gradient. For example said first proportion is a majority (for example over 50%) of the total amount of said media in said reaction vessel. For example said first proportion is less than 50% of the total amount of said media in said reaction vessel. For example, said fluid inlet is provided at a lower part of the reaction vessel and said fluid outlet is provided at an upper part of the reaction vessel. For example, said fluid inlet comprises a plurality of openings within said reaction vessel, and wherein said openings are distributed over a bottom base of the reaction vessel providing a desired coverage with respect to the bottom base. For example, said openings are uniformly distributed over a bottom base of the reaction vessel providing a full coverage with respect to the bottom base. For example, said reaction vessel comprises one or more draft tubes, each draft tube being configured to further increase said fluid velocity therein. For example, each said draft tube provides an initially decreasing flow area in the direction of flow therethrough. For example, said openings of said fluid inlet are uniformly distributed over a part of bottom base of the reaction vessel opposite said draft tubes providing a full coverage with respect to the draft tubes.
In at least a first example, at said predetermined velocity is sufficient to provide downward motion to said media having a density less than that of said liquid medium. For example, said flow velocity within said reaction vessel is in at least partially aligned with the gravitational gradient, and wherein at least a second proportion of said media has a density less than that of said liquid medium. For example, said second proportion is a majority of the total amount of said media in said reaction vessel. For example, said fluid inlet is provided at an upper part of the reaction vessel. For example, said reaction vessel comprises one or more draft tubes, each draft tube being configured to further increase said fluid velocity therein. For example, said openings of said fluid inlet are uniformly distributed over an upper opening of each said draft tubes providing a full coverage with respect to the draft tubes. For example, each said draft tube provides an initially decreasing flow area in the direction of flow therethrough.
The aerobic bioreactor according to the ninth aspect of the presently disclosed subject matter can optionally further comprise a first sludge receiving receptacle at a lower part thereof for receiving and disposing of sludge from the aerobic bioreactor.
Additionally or alternatively, the aerobic bioreactor further comprises a clarifying vessel on an upper part of said reaction vessel and in fluid communication therewith, wherein said fluid outlet is provided on said clarifying vessel, and wherein said clarifying vessel is configured for reducing said fluid velocity therein. For example, said clarifying vessel comprises a cross-sectional area that increases in an upward direction. For example, said clarifying vessel comprises a second sludge receiving receptacle at a lower part thereof for receiving and disposing of sludge from the clarifying vessel.
The aerobic bioreactor according to the ninth aspect of the presently disclosed subject matter can optionally further comprise an effluent outlet for removing processed effluent from said aerobic bioreactor.
According to a tenth aspect of the presently disclosed subject matter, there is provided a system for processing waste, comprising:

- an aerobic bioreactor as defined above regarding the ninth aspect of the presently disclosed subject matter;
- the source of oxygen-rich liquid medium as defined above regarding the ninth aspect of the presently disclosed subject matter, wherein said fluid inlet and said fluid outlet are connected to the source of oxygen-rich liquid medium; and
- the media as defined above regarding the ninth aspect of the presently disclosed subject matter, and provided in said aerobic bioreactor.

For example, the system according to the tenth aspect of the presently disclosed subject matter said system is configured for preventing the media from being transferred from the aerobic bioreactor to said source.
Additionally or alternatively, said media is restricted to a confined volume within said aerobic bioreactor.
Additionally or alternatively, said source comprises photosynthetic microorganisms that generate oxygen to said liquid medium responsive to exposure to light.
Additionally or alternatively, said source comprises any one of photosynthetic eukaryotic microorganisms and photosynthetic prokaryotic microorganisms that generate oxygen to said liquid medium responsive to exposure to light.
Additionally or alternatively, said source comprises algae that generate oxygen to said liquid medium responsive to exposure to light.
Additionally or alternatively, wherein said photosynthetic microorganisms comprise at least one of: Chlorella spp, spirulina, scendesmus, or any other photosynthetic microalgae or cyanobacteria.
Additionally or alternatively, said source comprises a reservoir comprising a channel therein defining a reservoir internal volume, and configured for driving said liquid medium around said channel in operation of the system.
Additionally or alternatively, the system further comprises an auxiliary aeration system, configured for selectively providing gaseous oxygen or air to said bioreactor.
Additionally or alternatively, the system further comprises an auxiliary CO₂system, configured for selectively providing carbon dioxide to said source.
Additionally or alternatively, a portion of said media is fixed in situ within the bioreactor.
For example, said media comprise biofilm carrier elements, in the form of solid inert substrates having a relatively large surface area to volume ratio.
Additionally or alternatively, the system comprises a waste inlet configured for receiving the waste and a dispensing outlet for dispensing treated effluent, and wherein:

- said internal volume is partially or fully shielded from light at least during operation of the system;
- said source comprises at least one reservoir defining a respective reservoir volume for accommodating a volume of said liquid medium, and further comprising a source fluid medium inlet and a source fluid medium outlet, each in selective fluid communication with said aerobic bioreactor, and a driving device for providing motion to said liquid medium within said respective reservoir volume, the at least one reservoir being configured for ensuring that the respective reservoir volume is exposed to light at least during operation of said source wherein to provide said oxygen-rich liquid medium.

For example, said driving device comprises a powered paddling device mounted to the respective said reservoir. For example, said at least one reservoir comprises at least one flow channel in the form of a horizontal endless loop. For example, said at least one flow channel has an annular plan form. For example, said source fluid medium outlet is configured for preventing outflow of said media therethrough.
For example, the system comprises:

For example, said waste is aerobically treatable for removing pollutants therefrom. For example, said waste is a liquid waste. For example, said waste comprises at least one of waste water; organic types of waste; at least one of animal, agricultural, industrial or human waste transported in water or another liquid medium.
According to other aspects of the presently disclosed subject matter there are provided systems and methods for aerobically processing waste, in which an aerobic bioreactor is in selective fluid communication with a source of oxygen-rich liquid medium. The aerobic bioreactor is configured for aerobically processing waste via bacteria fixed on media to provide processed effluent from the waste. The source of oxygen-rich liquid medium is different from the aerobic bioreactor.
A feature of at least some examples of the presently disclosed subject matter is that the energy requirement to generate and supply oxygen to the aerobic bioreactor is much less than would be the case if the oxygen is instead provided by an aerator or the like, for example an electromechanical aerator.
A feature of at least some examples of the presently disclosed subject matter is that, by separating the aerobic treatment process of waste from the process of generating oxygen via photosynthetic microorganisms (for example algae), interference between the two processes can be minimized or avoided.
A feature of at least some examples of the presently disclosed subject matter is that, by separating the aerobic treatment process of waste from the process of generating oxygen via photosynthetic microorganisms (for example algae), each process can be separately and independently optimized.
A feature of at least some examples of the presently disclosed subject matter is that, by providing bacteria fixed on media, the aerobic treatment process of waste can be easily separated from the process of generating oxygen via photosynthetic microorganisms (for example algae).
A feature of at least some examples of the presently disclosed subject matter is that, by providing bacteria fixed on media, the efficiency of the aerobic treatment of waste can be enhanced as compared with providing the bacteria without media.
A feature of at least some examples of the presently disclosed subject matter is that algae is produced as a byproduct of the waste treatment process. Thus, the waste treatment system and method of at least some examples of the presently disclosed subject matter is concurrently, or alternatively a system and method, respectively, for the production of algae, in which the algae can be harvested from the respective source of oxygen-rich liquid medium.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to understand the subject matter that is disclosed herein and to exemplify how it may be carried out in practice, examples will now be described, by way of non-limiting example only, with reference to the accompanying drawings, in which:

FIG. 1( a) and FIG. 1( b) are respectively a cross-sectional side view and a plan view of a system for aerobic processing of waste according to a first example of the presently disclosed subject matter.

FIG. 2( a) and FIG. 2( b) are respectively a cross-sectional side view and a plan view of a system for aerobic processing of waste according to a second example of the presently disclosed subject matter.

FIG. 3( a) and FIG. 3( b) are respectively a cross-sectional side view and a plan view of a system for aerobic processing of waste according to a third example of the presently disclosed subject matter.

FIG. 4( a) and FIG. 4( b) are respectively a cross-sectional side view and a plan view of a system for aerobic processing of waste according to a fourth example of the presently disclosed subject matter.

FIG. 5( a) and FIG. 5( b) are respectively a cross-sectional side view and a plan view of a system for aerobic processing of waste according to a fifth example of the presently disclosed subject matter.

FIG. 6 is a cross-sectional side view of an alternative variation of the example of FIG. 5( a) and FIG. 5( b).

FIG. 7( a), 7(b), 7(c) schematically illustrate operation of the example of FIG. 5( a) and FIG. 5( b) according to one example of a method of the presently disclosed subject matter.

FIG. 8 schematically illustrates operation of the example of FIG. 5( a) and FIG. 5( b) according to one example of a method of the presently disclosed subject matter.

FIG. 9 schematically illustrates operation of the example of FIG. 5( a) and FIG. 5( b) according to one example of a method of the presently disclosed subject matter.

FIG. 10 is a cross-sectional side view of an alternative variation of the example of FIG. 5( a) and FIG. 5( b).

FIG. 11 is a cross-sectional side view of an alternative variation of the example of FIG. 5( a) and FIG. 5( b).

DETAILED DESCRIPTION

Referring to FIGS. 1( a) and 1(b), a system for aerobic processing of waste, in particular liquid waste, according to a first example of the presently disclosed subject matter, generally designated 100, comprises an aerobic bioreactor 120 and an oxygen-rich liquid medium source 150.
Such waste includes but is not limited to organic types of waste, in particular waste water containing suspended or dissolved organic matter as well as nitrogenous components, for example animal, agricultural, industrial or human waste transported in water, and which can be aerobically treated to remove pollutants.
Aerobic bioreactor 120 comprises a vessel 122 and is configured for aerobically processing waste therein using suitable microorganisms and oxygen, the oxygen being provided via a supply of oxygen-rich liquid medium L that is controllably recirculated between the liquid medium source 150 and the aerobic bioreactor 120.
Vessel 122 comprises walls 124 and defines an internal volume 126 (of magnitude V1), the respective aerobic processing volume. The vessel 122 can have any desired or suitable shape, for example cylindrical, frusto-conical, parallelepiped, and so on, and is configured for preventing the internal volume 126 from being irradiated by electromagnetic radiation having wavelengths corresponding to at least a predetermined group and/or range of wavelengths. This predetermined group and/or range of wavelengths consists of electromagnetic wavelengths that promote growth of algae and the accompanying generation of oxygen by the algae. This predetermined group and/or range of wavelengths is referred to herein as “light”, and typically includes the visible light spectrum and other wavelengths associated with photosynthesis. Thus, for example, the vessel 122 can be free-standing and the walls 124 are opaque to light. Alternatively, the vessel 122 can have translucent or transparent (or indeed opaque) walls, but in use the vessel 122 is buried underground, or is kept in a darkened enclosure, or is covered with an opaque shield, opaque blanket, or other opaque covering.
Such shielding of the internal volume 126 from said light can be full shielding, i.e., fully 100% effective in preventing the internal volume 126 from being irradiated by said light. Alternatively, such shielding of the internal volume 126 from said light can be partial shielding, i.e., can be less than 100% effective, for example up to 60%, or 70% or 80% or 90% or 95% or 98% or 99%, or any other percentage value inbetween these examples of percentages. In alternative variations of this example of the system, the internal volume 126 has zero shielding from said light.
The liquid medium source 150 comprises reservoir 152 (also referred to herein interchangeably as a tank) and is configured for providing a supply of liquid medium L that is controllably recirculated between the reservoir 152 and the aerobic bioreactor 120.
The reservoir 152 is different from and/or separate from the aerobic bioreactor 120, comprises walls 154 which define an internal volume 156 (of magnitude V2), the respective reservoir algae growth volume. The internal volume 156 is different from and separate from the internal volume 126 of the aerobic bioreactor 120. The reservoir 152 can have any desired or suitable shape that is configured for allowing circulation of the liquid medium therein. In this example, the reservoir 152 has a classical “raceway” configuration, comprising a generally elongated rectangular planform 160 having generally rectilinear upstanding longitudinal walls 164 and rounded ends 162 at the longitudinal ends thereof. A dividing wall 165 is positioned between longitudinal walls 164 and laterally spaced therefrom, extending longitudinally from the center of planform 160 towards rounded ends 162, but leaving a spacing between each edge 166 of the dividing wall 165 and the respective end 162. An endless, oval-shaped horizontal channel 169 is thus defined in the reservoir 152, allowing endless flow of the liquid medium L around the channel 169, driven by driver 170. In this example, the driver 170 is a mechanical propulsion device, and comprises a powered paddling system, including a motor 172 operatively connected to a paddle wheel 174, which comprises a plurality of paddles radially radiating from an axle that is rotatably mounted to the reservoir 152. In operation, the paddle wheel 174 is partially submerged in the liquid medium L and is turned by the motor 172 thereby propelling the liquid medium L around the channel 169 continuously in an endless loop (see arrows K, FIG.(b)). In alternative variations of this example, other arrangements can be provided for mixing the algae in the reservoir 152, for example: a moving bridge device, a cable pulled device, and so on.
The reservoir 152 is configured for allowing the internal volume 156 to be irradiated by said light, i.e. by electromagnetic radiation having wavelengths at least in the aforesaid predetermined group and/or range of wavelengths. In this example, the reservoir 152 has an open top 153, and thus the channel 169 can have a U-shaped or V-shaped transverse cross-section, for example, allowing natural sunlight to reach the liquid medium L in the channel 169 up to a particular penetration depth. In this example, the channel 169 is configured having an operational depth D of liquid medium L similar to the aforesaid penetration depth, but in alternative variations of this example the channel 169 can be instead configured having operational depth D of liquid medium L greater than or less than the aforesaid penetration depth. The depth of the channel 169 can be uniform across the cross-section of the channel 169, or can vary therein. For example, depth D can vary across the width of the channel from 30 cm at the longitudinal walls 164 to more than 1 meter at the center of the channel 169, or, the entire width of the channel 169 can be about 60 cm deep, or, the depth at the longitudinal walls 164 can be greater than 60 cm and the center of the channel 169 the depth can be greater than 2 meters deep. Optionally, the top 153 can be covered with a translucent or transparent cover, allowing said light to penetrate, but preventing contaminants from entering, the internal volume 156.
In this example the reservoir 152 is configured for operation in an outdoors environment. However, in alternative variations of this example the reservoir 152 can be configured for operation in an indoors environment, for example a greenhouse-type structure wherein such light may be provided via glass panels, or for example other natural or artificial structures in which such light is provided artificially via suitable illuminating apparatus such as electrical lamps, for example. Thus, the system 100 can optionally comprise illuminating apparatus such as lamps, for continual use, or for periodic use, for example during nighttime or low sunlight/overcast conditions.
System 100 comprises a recirculation circuit 180, having a reservoir outward flow path 181 and a reservoir return flow path 183 for recirculating the liquid medium L between the aerobic bioreactor 120 and the reservoir 150, in particular between the internal volume 126 and the internal volume 156. The reservoir outward flow path is provided by conduit 184, which provides fluid communication, in particular liquid communication, between bioreactor inlet 128 and reservoir outlet 158. The reservoir return flow path is provided by conduit 182, which thus provides fluid communication, in particular liquid communication, between bioreactor outlet 127 and reservoir inlet 157.
In this example, the recirculation circuit 180 further comprises a pump 185 for driving the aforesaid recirculation of the liquid medium L between the aerobic bioreactor 120 and the reservoir 150. For example, such a pump 185 can be a submersible pump, for example: XFP-8c-201g provided by ABS of Malmo, Sweden; or pump D-3000 provided by Flygt, of Stockholm, Sweden; or a dry mounted external pump, for example FR provided by ABS of Malmo, Sweden; or pump N-3000 provided by Flygt, of Stockholm, Sweden; or pump DWK, provided by Grundfoss of Bjerringbo, Denmark.
Optionally, part of the pumping may be carried out via gravity, and thus pump 185 can optionally comprise a gravity pump system. For example, flow of liquid medium L along the reservoir outward flow path 181 is via gravity, while a powered pump forces the flow of liquid medium L through the reservoir return flow path 183, or, flow of liquid medium L along the reservoir return flow path 183 is via gravity, while a powered pump forces the flow of liquid medium L through the reservoir outward flow path 181.
The liquid medium source 150, in particular the reservoir 152, is configured for generating and providing oxygen to liquid medium L, so that the oxygen-rich liquid medium L can be provided to the aerobic bioreactor 120 (via conduit 184). The generation of oxygen is accomplished by the photosynthetic action of photosynthetic microorganisms, in particular photosynthetic eukaryotic or prokaryotic microorganisms for example algae, (that are carried in the liquid medium L), when illuminated by said light and provided with appropriate nutrients. In this example, in which the reservoir 152 has an open top 153, carbon in the form of CO₂is provided from the atmosphere by natural diffusion via the surface of the liquid medium L, and nutrients required for the biological process are provided from the incoming waste water.
Such photosynthetic microorganisms can include any suitable photosynthetic eukaryotic microorganisms or photosynthetic prokaryotic microorganisms. For example, suitable photosynthetic eukaryotic microorganisms include algae, for example any one of the following: Chlorella, Scenedesmus, Spirulina, diatoms, and so on. In addition, suitable photosynthetic prokaryotic microorganisms include cyanobacteria (also known as “blue-green algae”) that can also serve as a photosynthetic source of oxygen.
Thus, while the disclosure herein refers to algae per se, it is to be noted that the disclosure applies, mutatis mutandis, to any other photosynthetic eukaryotic or prokaryotic microorganisms, for example as listed above.
The algae are thoroughly mixed within liquid medium L and are continually or cyclically exposed to the illuminating light by the motion around the channel 169 provided by driver 170, and the oxygen produced by the algae is dissolved in the liquid medium L.
The system 100 further comprises a waste inlet 132 (optionally including a valve, not shown) at the aerobic bioreactor 120 for receiving waste into the internal volume 126 and that is to be treated aerobically by the system 100. The system also comprises a treated effluent outlet 134 with valve 131, for dispensing treated effluent that results from aerobically treating the waste that is supplied to the aerobic bioreactor 120. While in this example, the effluent outlet 134 is provided at the reservoir 152, in alternative variations of this example the effluent outlet 134 can instead be provided at the aerobic bioreactor 120.
In the illustrated example of FIGS. 1( a) and 1(b), the aerobic bioreactor 120 and oxygen-rich liquid medium source 150 are shown in side-by-side configuration in system 100. However, in alternative variations of this example the aerobic bioreactor 120 and oxygen-rich liquid medium source 150 can have any suitable relative spatial relationship: for example, the aerobic bioreactor 120 can be positioned beneath the oxygen-rich liquid medium source 150.
As already mentioned, the aerobic bioreactor 120 is configured for aerobically processing waste using suitable microorganisms and oxygen provided by oxygen-rich liquid medium L. Such microorganisms can include for example any one of the following: saprophytic bacteria, heterotrophic bacteria, autotrophic bacteria, protozoa, metazoa, rotifers, and others.
In particular, the microorganisms are fixed on media 190. Such media 190 comprise biofilm carrier elements, in the form of substrates, in particular solid inert substrates, having a relatively large surface area to volume ratio R. Such substrates can include, for example, any one of polyethylene or other plastics, and the respective surface area to volume ratio R can be, for example, between about 500 m²/m³and about 1300 m²/m³, for example about 650 m²/m³. Alternatively, substrates can include, for example, any one of metallic materials, fibers, cloths, mineral materials (such as for example carbon, volcanic tuff, gravel), and so on, at least some of which can have respective surface area to volume ratios R much higher than 1300 m²/m³.
These substrates thus enable large amounts of microorganisms to be fixed on the surface of the substrates as a biofilm, provide a stable matrix for the microorganisms, support aerobic, facultative or anaerobic consortia of microorganisms, and allow optimal interaction between the microorganisms and the waste, which the microorganisms digest aerobically utilizing the dissolved oxygen provided by the liquid medium L.
In this example, the media 190 are mobile, i.e. free-floating media, configured for moving within the liquid mixture Q in the internal volume 126, the liquid mixture Q including liquid medium L, waste W, and processed effluent E in varying proportions during operation of the system 100.
In this example, the free-floating media 190 are prevented from leaving the aerobic bioreactor 120 and from being transported via recirculation circuit 180 to the reservoir 152, at least during operation of the system 100. For this purpose the aerobic bioreactor 120 comprises suitable mechanical filters, screens or other selective barriers (not shown) at the bioreactor outlet 127, and optionally also at the bioreactor inlet 128, that prevent passage of the media 190 therethrough, while allowing flow of the liquid medium L therethrough.
Examples of such media 190 include one or more of the following: Aqwise Biomass Carriers (ABC 5), provided by Aqwise, Israel; biocarriers K1 or K3, provided by Veolia, France, ActivCell provided by Degremont, France.
In alternative variations of this example, media 190 is, or also additionally comprises, fixed media. Such fixed media are affixed in situ with respect to the location thereof within the internal volume 126, and thus are prevented from leaving the aerobic bioreactor 120 and from being transported via recirculation circuit 180 to the reservoir 152, even in the absence of mechanical filters or screens at the bioreactor outlet 127 and/or at the bioreactor inlet 128. Such fixed media includes types of media in which the substrate is fixed on one or more sides thereof to the structure of the vessel 122. For example, such fixed media can be in the form of a plastic matrix attached to the floor or sides of the vessel 122, and/or ropes or fibers hanging within the liquid in the vessel 122 and attached either to the walls or other structure of the vessel 122 or attached to a rigid frame located within the vessel 122. Examples of such fixed media can include one or more of the following: AccuFAS PVC carrier material, provided by Brentwood Corporation, USA; Bioclere media material provided by Aquapoint, USA; Ringlace biomaedia provided by Ringlace Products, USA.
Alternatively, the fixed media is not necessarily actually attached to the inside of the aerobic bioreactor, but rather comprises a quantity of media which by virtue of its own weight (e.g., a pile of gravel media) remains in a single location in the aerobic bioreactor.
In this example, the aerobic bioreactor 120 further comprises a mixing device 149, configured for mixing the media 190 within the liquid mixture Q, while minimizing or preventing damage to the media 190. In this example, the mixing device comprises a powered stirrer, for example for example submersible mixers POPR-I provided by Landia, of Sweden, or mixer RW-400 provided by ABS of Sweden, or mixer 4850 top entry mixer provided by Flygt, of Sweden.
Optionally, the system 100 can further comprise an auxiliary aeration system, (not shown) configured for selectively providing gaseous oxygen or air to the aerobic bioreactor 120, for example comprising a pump or source of compressed air having an outlet in selective communication with the internal volume 126. Such an auxiliary aeration system can be used, for example, during operation of system 100 at nighttime or in low sunlight/overcast conditions, or whenever oxygen production by the source 150 is lower than required, or indeed whenever desired.
Optionally, the system 100 can further comprise an auxiliary CO₂system, (not shown) configured for selectively providing gaseous carbon dioxide or carbon-dioxide rich air to the liquid source 150, for example comprising a pump or source of compressed gaseous carbon dioxide or carbon-dioxide rich air having an outlet in selective communication with the internal volume 156. Such an auxiliary CO₂system can be used, for example, whenever additional CO₂is required for oxygen production by the source 150, or indeed whenever desired.
Operation of system 100 in a continuous flow mode (CFM) can be as follows.
Waste W, mainly in liquid form, is conveyed to the aerobic bioreactor 120 at a flow rate T1 via waste inlet 132, the waste W first having first been subjected to preprocessing, including a screening and degritting process to remove solids, with or without a preliminary anaerobic treatment process. Concurrently, there is provided a recirculating flow of liquid medium L between the reservoir 152 and the aerobic bioreactor 120 via recirculation circuit 180, at a flow rate T2. The liquid medium L also carries algae to and from the reservoir 152 via recirculation circuit 180. The liquid medium L in reservoir 152 is being continuously provided with oxygen generated by the algae therein as the liquid medium L is exposed to said light and provided with nutrients, and this oxygen generation process is enhanced by forcing the liquid medium L to flow along channel 169 by the action of the driver 170. Thus, the liquid medium L delivered to the aerobic bioreactor 120 via conduit 184 is oxygen-rich.
The microorganisms fixed in media 190 treat the waste aerobically, using oxygen dissolved in the liquid medium L delivered from the reservoir 152, thereby converting the waste W into processed effluent E. The effluent E leaves the aerobic bioreactor 120 via conduit 182 under the action of pump 185, and flows into the reservoir 152, to be dispensed via dispensing outlet 134 at flow rate T3.
In practice, a mixture M1 of the processed effluent E, (partially de-oxygenized) liquid medium L, and possibly waste W, in varying proportions, leaves the aerobic bioreactor 120 via conduit 182. Similarly, a mixture M2 of the processed effluent E, (oxygen-rich) liquid medium L, and possibly waste W, in varying proportions, circulates back and enters the aerobic bioreactor 120 via conduit 184. Similarly, a mixture M3 of the processed effluent E, liquid medium L, and possibly waste W, in varying proportions, is dispensed via the dispensing outlet 134. However, the system 100 is also set up such that in steady-state operating conditions, mixture M1 has a high proportion of effluent E relative to waste W, mixture M2 has a high proportion of liquid medium L relative to waste W or effluent E, and mixture M3 has a high proportion of effluent E relative to waste W.
This effect can be achieved as follows, for example. In steady state conditions, the waste input flow rate T1 is about the same as effluent output flow rate T3, and the liquid medium L flow rate recirculating between the reservoir 152 and the aerobic bioreactor 120 T2 is greater than flow rate T1 or T3; for example T2 can be from 2 to 10 times greater than T1 or T3. At the same time, the flow rates T1, T2, T3 are such (when compared with the sizes V1 and V2, respectively, of internal volumes 126 and 156) so as to allow the waste W sufficient residence time (also referred to interchangeably herein as retention time) in the aerobic bioreactor 120 to become processed by the microorganisms in the media 190, and so as to allow the algae sufficient residence time in the reservoir 152 to generate the required levels of oxygen therein.
For example, the volume ratio V2/V1 of the respective internal volumes 126 and 156 can be between about 1 to about 10, or greater; additionally or alternatively, the retention time ratio V1/T1 or V1/T3 can be between about 5 hours to about 20 hours or greater, for example 8 hours; additionally or alternatively, the retention time ratio V1/T2 can be between about 1.0 hours to about 20 hours or greater, for example 2.7 hours; additionally or alternatively, the retention time ratio V2/T1 or V2/T3 can be between about 10 hours to about 40 hours or greater, for example 24 hours; additionally or alternatively, the retention time ratio V2/T2 can be between about 3 hours to about 20 hours or greater, for example 8 hours.
For example, the internal volume 126 can be configured for providing a retention time for the waste therein of between 2 to 12 hours, for a given flow rate T1 of waste W into the aerobic bioreactor 120. For example, the internal volume 156 can be configured for providing a retention time for the liquid medium L including algae therein of between 8 to 72 hours, for a given flow rate T2 of liquid medium L into (and out of) the aerobic bioreactor 120 via recirculation circuit 180.
For example, to provide this effect, the internal volume 126 can be about 400 liters, waste flow rate T1 into the aerobic bioreactor 120 can be about 50 liters/hour, the internal volume 156 can be about 1200 liters, the liquid medium flow rate T2 into the aerobic bioreactor 120 can be about 150 liters/hour, and the processed effluent flow rate T3 out of the system 100 can be about 50 liters/hour. In another example this effect can be provided with the following parameters: the internal volume 126 can be about 400 cubic meters, waste flow rate T1 into the aerobic bioreactor 120 can be about 50 m³/hour, the internal volume 156 can be about 1200 cubic meters, the liquid medium flow rate T2 into the aerobic bioreactor 120 can be about 350 m³/hour, and the processed effluent flow rate T3 out of the system 100 can be about 50 m³/hour. Of course, other examples of the magnitude of the flow rates T1, T2, T3 and of the magnitudes V1, V2, respectively of the internal volume 126 and the internal volume 156, can be chosen to provide the aforementioned effect.
Thus, in operation of the system 100, the microorganisms aerobically treat the waste W in internal volume 126 and in the absence of said light, i.e., in darkened conditions, which are optimal for the microorganisms, while being provided with ample oxygen dissolved in the liquid medium L. In the darkened conditions provided by the aerobic bioreactor 120, the algae that is recirculating through the aerobic bioreactor 120 are thus under conditions that do not promote further growth, and thus minimize interference with the aerobic processing of the waste by the microorganisms. Furthermore, the provision of the microorganism as a biofilm fixed on media 190, in which the microorganism are exposed to the waste W and oxygen-rich liquid medium L over a large surface area relative to the volume occupied by the media 190, enables the waste W to be processed faster and more efficiently than would be the case if the microorganism were instead provided as a sludge moving throughout the system, for example.
On the other hand, the conditions for generating oxygen by the algae in source 150 are also concurrently optimal, the algae receiving said light and nutrients in the reservoir 152, and kept in motion around the channel 169 by the action of the driver 170. Further, these conditions are further optimized by the relative absence of the microorganisms in the reservoir 152, since the microorganisms, being fixed on the media 190, are prevented from being transported to the reservoir 152 from the aerobic bioreactor 120.
Thus, the aerobic treatment process of waste is independent and separated from the process of generating oxygen via algae, avoiding or minimizing interference between the two processes, and each process can be separately and independently optimized.
For a given requirement of throughput of waste through the aerobic bioreactor 120, the reservoir 152 can be sized accordingly whereby to provide the necessary oxygen demand for the bioreactor 120.
The energy requirements for operating the system 100 are thus relatively modest, including the power required for operating the pumps 185,149, and the driver 170.
The system 100 can optionally further comprise post-processing systems for post-processing the effluent E. For example, downstream of effluent outlet 134 can be provided further filters and purifiers to further purify the effluent E. For example, a plurality of systems 100 can be connected in series, with the first one receiving waste W, and having its effluent outlet 134 connected to the waste inlet 132 of the next system 100 (thus the effluent from the first system is considered as the “waste” being supplied to the next system), which is similarly connected to the next system, and so on, the last system 100 then dispensing the many-times processed effluent E.
It is to be noted that the aerobic processing of the waste in the aerobic bioreactor 120 generates CO₂as a byproduct, and this CO₂can be routed to the reservoir 152 (via suitable piping or the existing liquid flows, for example) to provide additional carbon to the algae therein. Alternatively, the biogas itself, which is rich in CO₂, can be used to enrich the algae with a carbon source by injecting it through the liquid medium L.
It is also to be noted that in the aforementioned preprocessing in the form of said anaerobic treatment process, biogas can be generated. This biogas can be sold off, or can be utilized for power generation, for example for powering the system 100, and the CO₂produced as a byproduct of said power generation can also be routed to the reservoir 152 via suitable piping for example to provide additional nutrients to the algae therein.
Alternatively, system 100 can be operated in batch mode (BM), for example as follows. Waste W (after the aforesaid preprocessing) is provided to the aerobic bioreactor 120 until it reaches a particular level. The waste input is turned off at waste inlet 128, and the effluent outlet 134 is also closed. The reservoir is operated as in CFM above, mutatis mutandis, to provide a flow rate of liquid medium L through aerobic bioreactor 120, providing oxygen to the aerobic bioreactor 120, and allowing the aerobic bioreactor 120 and the reservoir to each operate under its own optimal conditions, but without continuous addition of waste W or dispensing of effluent E. The microorganisms that are fixed on media 190 aerobically process the waste in a similar to that of the CFM disclosed above, mutatis mutandis, typically by digesting or decomposing the waste, and when all or most of the waste is processed, the processed effluent can be drained from the aerobic bioreactor 120 or via the reservoir 152, through the correspondingly-located effluent outlet 131, though in practice such effluent is mixed in with liquid medium L.
Referring to FIGS. 2( a) and 2(b), a second example of the system, generally designated 200, comprises the elements and features of system 100 of the first example and operates in a similar manner thereto, mutatis mutandis, but with some differences, as will become clearer herein. Thus, system 200 comprises aerobic bioreactor 220 and an oxygen-rich liquid medium source 250, similar to aerobic bioreactor 120 and oxygen-rich liquid medium source 150, mutatis mutandis, but with some differences.
Liquid medium source 250 comprises reservoir 252 (similar to reservoir 152, mutatis mutandis) and is configured for providing a supply of liquid medium L that is controllably recirculated between the reservoir 252 and the aerobic bioreactor 220. Liquid medium source 250 is different from and separate from the aerobic bioreactor 220.
The reservoir 252 similarly comprises walls 254 and defines an internal volume 256, different from and separate from the internal volume 226 of the aerobic bioreactor 220. While in alternative variations of this example the reservoir 252 can have any suitable shape, in this example the reservoir has a classical “raceway” configuration, similar to the reservoir 152 of the first example, mutatis mutandis, comprising a generally elongated rectangular planform 260, including generally rectilinear upstanding longitudinal walls 264, rounded ends 262, dividing wall 265, endless oval-shaped horizontal channel 269 allowing endless flow of the liquid medium L around the channel 269, driven by driver 270, respectively similar in form and function to: planform 160, generally rectilinear upstanding longitudinal walls 164, rounded ends 162, dividing wall 165, endless oval-shaped horizontal channel 169 and driver 170, mutatis mutandis. As with the first example, mutatis mutandis, the reservoir 252 is configured for allowing the internal volume 256 to be irradiated by said light, i.e. by electromagnetic radiation at least of the aforesaid predetermined group and/or range of wavelengths, and in the second example the reservoir 252 also has an open top 253, which optionally, can be covered with a translucent or transparent cover, allowing light to penetrate, but preventing contaminants from entering, the internal volume 256.
Aerobic bioreactor 220 comprises a vessel 222 and is configured for aerobically processing waste therein using suitable microorganisms and oxygen, in a similar manner to aerobic reactor 120 and vessel 122, mutatis mutandis, but with some differences, as will become clearer herein. This oxygen is provided via a supply of oxygen-rich liquid medium L that is controllably recirculated between the liquid medium source 250 and the aerobic bioreactor 220.
Vessel 222 comprises walls 224 and defines an internal volume 226. Vessel 222 can have any desired or suitable shape, and is configured for preventing the internal volume 226 from being irradiated by said light, and comprises microorganisms fixed in media 190, in a similar manner as disclosed herein for vessel 122 and media 190 of the first example, mutatis mutandis.
In the second example, vessel 222 located beneath the reservoir 252 and both components can optionally be constructed as an integral structure, or as two separate structures joined together.
In the second example, the respective recirculation circuit 280 is also configured for recirculating the liquid medium L between the aerobic bioreactor 220 and the reservoir 250, in particular between the internal volume 226 and the internal volume 256. The recirculation circuit 280 also has a reservoir outward flow path and a reservoir return flow path, but differs from the recirculation circuit 180 of the first example as follows. The reservoir outward flow path to the aerobic bioreactor 220 is via bioreactor inlet 228 which also acts as the reservoir outlet 258, while the reservoir return flow path is via conduit 284 that connects bioreactor outlet 227 with reservoir inlet 257.
The bioreactor inlet 228/reservoir outlet 258 is located at an upper portion of the vessel 222, and also located in the channel 269 and submerged within the liquid medium L therein at least during operation of the system 200. The recirculation circuit 280 further includes a valve arrangement 281 for selectively controlling what proportion of the flow of liquid medium L around the circuit 269 is diverted to the aerobic bioreactor 220. In the illustrated example, the valve arrangement 281 is in the form of a movable weir, pivotably mounted at the bioreactor inlet 228/reservoir outlet 258 and operates to pivot about the respective pivot axis to change the effective inlet area of the bioreactor inlet 228/reservoir outlet 258.
The bioreactor outlet 227 is located at a lower portion of the vessel 222, while reservoir inlet 257 opens into the channel 269 and submerged within the liquid medium L therein at least during operation of the system 200.
In this example, the free-floating media 190 are also prevented from leaving the aerobic bioreactor 220 and from being transported via recirculation circuit 280 to the reservoir 252, at least during operation of the system 200. For this purpose the aerobic bioreactor 220 comprises suitable mechanical filters or screens 289 at the bioreactor outlet 227, and optionally also at the bioreactor inlet 228/reservoir outlet 258 (not shown), that prevent passage of the media 190 therethrough, while allowing flow of the liquid medium L therethrough. Alternatively, free-floating media 190 can be replaced with fixed media as in the first example of system 100, mutatis mutandis and no such filters or screens are necessary and can be omitted.
In this example, the recirculation circuit 280 further comprises a pump 285 for driving the aforesaid recirculation of the liquid medium L between the aerobic bioreactor 220 and the reservoir 252. In the illustrated example, such a pump 285 is in the form of an airlift pump, powered by a blower, and located at the bottom end of the conduit 284. Such an airlift pump may comprise, for example, one or more of the following: Robox provided by Robuschi of Italy, or Delta Blower provided by Aerzen, of the USA; or Roots Blowers provided by GE of the USA. Optionally, the air introduced into the conduit 284 by the airlift pump can be enriched in CO₂, or can be replaced with CO₂, which can enhance growth of the algae in the reservoir 252 and generation of oxygen. In alternative variations of this example, pump 285 can have any other suitable form, for example similar to pump 185 as disclosed above for the first example, mutatis mutandis.
In this example, the aerobic bioreactor 220 can optionally further comprise a mixing device (not shown), for example similar to the mixing device 149 of the first example of system 100, mutatis mutandis, and is configured for mixing the media 190 within the liquid mixture Q in the vessel 222, while minimizing or preventing damage to the media 190.
System 200 also comprises a waste inlet 232 and a processed effluent outlet 234, which in this example are provided in the reservoir 252 but in other alternative variations of this example can be provided directly to reservoir 220 instead.
Operation of the system 200 in CFM or in BM is as disclosed above for the first example of system 100 optionally including preprocessing and/or post-processing, mutatis mutandis, with the main difference being that the respective flow rate T2 of recirculating flow of liquid medium L between the reservoir 252 and the aerobic bioreactor 220 via recirculation circuit 280, is controlled by the flow rate of the liquid medium L around the channel 269 coupled with the effective flow area at the bioreactor inlet 228/reservoir outlet 258, which is controlled by the valve arrangement 281 and by the flow of air from pump 285.
Referring to FIGS. 3( a) and 3(b), a third example of the system, generally designated 300, comprises the elements and features of system 100 of the first example (or similarly of system 200 of the second example) and operates in a similar manner thereto, mutatis mutandis, but with some differences, as will become clearer herein. Thus, system 300 comprises aerobic bioreactor 320 and an oxygen-rich liquid medium source 350, similar to aerobic bioreactor 120 and oxygen-rich liquid medium source 150, mutatis mutandis, but with some differences.
Liquid medium source 350 comprises reservoir 352, which similarly to reservoir 152, mutatis mutandis, is configured for providing a supply of liquid medium L that is controllably recirculated between the reservoir 352 and the aerobic bioreactor 320, and is different from and separate from the aerobic bioreactor 320.
The reservoir 352 similarly comprises walls 354 and defines an internal volume 356, different from and separate from the internal volume 326 of the aerobic bioreactor 320. While in alternative variations of this example the reservoir 352 can have any suitable shape, in this example the reservoir has a modified “raceway” configuration, similar to the reservoir 152 of the first example, mutatis mutandis, but in which the dividing wall 165 is replaced with a cylindrical wall 365. Thus, reservoir 352 comprises a generally annular planform 360, including generally cylindrical upstanding outer wall 364, and the inner said cylindrical wall 365, defining an endless annular-shaped horizontal channel 369 allowing endless flow of the liquid medium L around the channel 369, driven by driver 370, the channel 369 and driver 370 being respectively similar in form and/or function to endless oval-shaped horizontal channel 169 and driver 170, mutatis mutandis. As with the first example, mutatis mutandis, the reservoir 352 is configured for allowing the internal volume 356 to be irradiated by said light, i.e. by electromagnetic radiation at least of the aforesaid predetermined group and/or range of wavelengths, and in the third example the reservoir 352 also has an open top 353, which optionally, can be covered with a translucent or transparent cover, allowing light to penetrate, but preventing contaminants from entering, the internal volume 356.
Aerobic bioreactor 320 comprises a vessel 322 and is configured for aerobically processing waste therein using suitable microorganisms and oxygen, in a similar manner to aerobic reactor 120 and vessel 122, mutatis mutandis, but with some differences, as will become clearer herein. This oxygen is provided via a supply of oxygen-rich liquid medium L that is controllably recirculated between the liquid medium source 350 and the aerobic bioreactor 320.
Vessel 322 comprises walls 324 and defines an internal volume 326. Vessel 322 can have any desired or suitable shape, is configured for preventing the internal volume 326 from being irradiated by said light, and comprises microorganisms fixed in media 190, in a similar manner as disclosed herein for vessel 122 and media 190 of the first example, mutatis mutandis.
In the third example, vessel 322 located within the inner wall 365 and extends to a depth below that of the reservoir 352, and both components can optionally be constructed as an integral structure, or as two separate structures joined together. In particular, the outer cylindrical walls 324 of vessel 322 can act as inner cylindrical wall 365. Alternatively, in alternative variations of this example, the vessel 322 can be spaced from inner cylindrical wall 365 by a gap. For example, the vessel 322 can have a depth of between about 1 m and about 10 m.
In the third example, the respective recirculation circuit 380 is also configured for recirculating the liquid medium L between the aerobic bioreactor 320 and the reservoir 350, in particular between the internal volume 326 and the internal volume 356. The recirculation circuit 380 also has a reservoir outward flow path and a reservoir return flow path, but differs from the recirculation circuit 180 of the first example as follows.
The reservoir outward flow path to the aerobic bioreactor 320 is via bioreactor inlet 328 which also acts as the reservoir outlet 358, while the reservoir return flow path is via conduit 384 that connects bioreactor outlet 327 with reservoir inlet 357.
The bioreactor inlet 328/reservoir outlet 358 is located at an upper portion of the vessel 322, and also located in the channel 369 and submerged within the liquid medium L therein at least during operation of the system 300. The bioreactor inlet 328/reservoir outlet 358 opens into a conduit 383 within vessel 322, having an upper opening 388 and a lower opening 387 within internal volume 326.
The bioreactor outlet 327 is located at an upper portion of the vessel 322, well above the level of liquid medium L in the channel 369, and the reservoir inlet 357 is also located above the reservoir 352, and liquid flows along the reservoir return flow path from the aerobic bioreactor 320 to the reservoir 352 when the level of liquid in the aerobic bioreactor 320 tries to exceed the level of the bioreactor outlet 327. In alternative variations of this example, the bioreactor outlet 327 and/or the reservoir inlet 357 can be located elsewhere in the system 300, for example the reservoir inlet 357 can be located in the channel 369 and submerged within the liquid medium L therein at least during operation of the system 300.
In this example, the recirculation circuit 380 further comprises a pump 385 for driving the aforesaid recirculation of the liquid medium L between the aerobic bioreactor 320 and the reservoir 352. In the illustrated example, such a pump 385 is in the form of an airlift pump, powered by a compressor, and located at the bottom end of the conduit 383, near lower opening 387. Such an airlift pump may comprise, for example, any one of; Robox provided by Robuschi of Italy; or Delta Blower provided by Aerzen, of the USA; or Roots Blowers, provided by GE of the USA. As a gas such as air is introduced into conduit 383, an upward flow is induced in conduit 383, drawing in fluid from internal volume 326, which in turn acts as a venture at the bioreactor inlet 328/reservoir outlet 358 to draw in liquid medium from the channel 369. Thus, pump 385 is located close to the bioreactor inlet 328/reservoir outlet 358.
Optionally, the air introduced into the conduit 383 by the airlift pump can be enriched in CO₂, or can be replaced with CO₂, which can enhance growth of the algae in the reservoir 352 and generation of oxygen. In alternative variations of this example, pump 285 can have any other suitable form, for example similar to pump 185 as disclosed above for the first example, mutatis mutandis. In operation of the system 300, the CO₂is entrained and dissolved in the liquid in the aerobic reactor 320, and subsequently flows out the aerobic reactor 320 and into the reservoir 352 together with this liquid. In alternative variations of this example, the pump 385 can be located at bioreactor outlet 327 instead of close to the bioreactor inlet 328/reservoir outlet 358, mutatis mutandis, thereby increasing efficiency of the CO₂usage; in such an example, the hydraulic relationship between the aerobic reactor 320 and the reservoir 352 can be changed, with the level of liquid of the aerobic reactor 320 being lower than the level of liquid in the reservoir 352 (in contrast, in the example illustrated in FIG. 3( a), the level of liquid of the aerobic reactor 320 is higher than the level of liquid in the reservoir 352).
In this example, the free-floating media 190 are also prevented from leaving the aerobic bioreactor 320 and from being transported via recirculation circuit 280 to the reservoir 352, at least during operation of the system 300. For this purpose the aerobic bioreactor 320 comprises suitable mechanical filters or screens (not shown) at the bioreactor outlet 327, and optionally also at the bioreactor inlet 328/reservoir outlet 358 (not shown), that prevent passage of the media 190 therethrough, while allowing flow of the liquid medium L therethrough. Alternatively, free-floating media 190 can be replaced with fixed media as in the first example of system 100, mutatis mutandis and no such filters or screens are necessary and can be omitted.
In this example, the aerobic bioreactor 320 further comprises a mixing device 349, similar to the mixing device 149 of the first example of system 100, and is configured for mixing the media 190 within the liquid mixture Q in the vessel 322, while minimizing or preventing damage to the media 190. In this example, the mixing device comprises a powered stirrer, which can be for example any one of the following: submersible mixers POPR-I provided by Landia, of Sweden; or mixer RW-400 provided by ABS of Sweden; or mixer 4850 top entry mixer provided by Flygt, of Sweden.
System 300 also comprises a waste inlet 332, provided into the aerobic bioreactor 320, and a processed effluent outlet 334, which in this example is provided in the reservoir 352.
Operation of the system 300 in CFM or in BM is as disclosed above for the first example of system 100 or second example of system 200 optionally including preprocessing and/or post-processing, mutatis mutandis, with the main difference being that the respective flow rate T2 of recirculating flow of liquid medium L between the reservoir 352 and the aerobic bioreactor 320 via recirculation circuit 380, is controlled by the flow rate of the liquid medium L around the channel 369 coupled with the pumping action of pump 385, and providing a more compact layout.
Referring to FIGS. 4( a) and 4(b), a fourth example of the system, generally designated 400A, comprises two self-contained systems 400 operating in parallel, though in other alternative variations of this example the system 400A can comprise only one system 400. In yet other alternative variations of this example the system 400A can comprise more than two systems 400, operating in parallel or in series, or two systems 400 operating in series, or any other combination or permutation of two or more two systems 400, mutatis mutandis.
Each system 400 comprises the elements and features of system 100 of the first example, and in particular of the system 200 of the second example and operates in a similar manner thereto, mutatis mutandis, but with some differences, as will become clearer herein. Each system 400 comprises an aerobic bioreactor 420 and an oxygen-rich liquid medium source 450, similar to aerobic bioreactor 120 and oxygen-rich liquid medium source 150, mutatis mutandis, but with some differences.
Liquid medium source 450 comprises reservoir 452 (similar to reservoir 152, mutatis mutandis, is configured for providing a supply of liquid medium L that is controllably recirculated between the reservoir 452 and the aerobic bioreactor 420, and is different from and separate from the aerobic bioreactor 220.
The reservoir 452 similarly comprises walls 454 and defines an internal volume 456, different from and separate from the internal volume 426 of the aerobic bioreactor 420. While in alternative variations of this example the reservoir 252 can have any suitable shape, in this example the reservoir also has a classical “raceway” configuration, similar to the reservoir 152 of the first example, mutatis mutandis, comprising a generally elongated rectangular planform 460, including generally rectilinear upstanding longitudinal walls 464, rounded ends 462, dividing wall 465, endless oval-shaped horizontal channel 469 allowing endless flow of the liquid medium L around the channel 469, driven by driver 470, respectively similar in form and function to: planform 160, generally rectilinear upstanding longitudinal walls 164, rounded ends 162, dividing wall 165, endless oval-shaped horizontal channel 169 and driver 170, mutatis mutandis. As with the first example, mutatis mutandis, the reservoir 452 is configured for allowing the internal volume 456 to be irradiated by said light, i.e. by electromagnetic radiation at least of the aforesaid predetermined group and/or range of wavelengths, and in the second example the reservoir 452 also has an open top 453, which optionally, can be covered with a translucent or transparent cover, allowing light to penetrate, but preventing contaminants from entering, the internal volume 456.
Aerobic bioreactor 420 comprises a vessel 422 and is configured for aerobically processing waste therein using suitable microorganisms and oxygen, in a similar manner to aerobic reactor 120 and vessel 122, mutatis mutandis, but with some differences, as will become clearer herein. This oxygen is provided via a supply of oxygen-rich liquid medium L that is controllably recirculated between the liquid medium source 450 and the aerobic bioreactor 420.
Vessel 422 comprises walls 424 and defines an internal volume 426. Vessel 422 can have any desired or suitable shape, and is configured for preventing the internal volume 426 from being irradiated by said light, and comprises microorganisms fixed in media 190, in a similar manner as disclosed herein for vessel 122 and media 190 of the first example, mutatis mutandis. Optionally, walls 424 can in fact be parts of the walls 454 of the reservoir 452.
In the fourth example, vessel 422 is located within the reservoir 452, in particular vessel 422 is accommodated in the channel 469, and both components—vessel 422 and the reservoir 452—can optionally be constructed as an integral structure, or as two separate structures joined together.
In the fourth example, the respective recirculation circuit 480 is provided directly by the circulating flow in the channel 469, which directly recirculates the liquid medium L between the aerobic bioreactor 420 and the channel 469 in reservoir 452, in particular between the internal volume 426 and the internal volume 456. The recirculation circuit 480 also has a reservoir outward flow path and a reservoir return flow path, but differs from the recirculation circuit 180 of the first example as follows. The reservoir outward flow path to the aerobic bioreactor 420 is via bioreactor inlet 428 which is in open communication with the reservoir outlet 458 at the channel 469, while the reservoir return flow path is via bioreactor outlet 427 which is in open communication with the reservoir inlet 457 at the channel 469. Thus, as liquid medium L is forced around the channel 469 using driver 470, it is also passed through the aerobic bioreactor 420, and no additional pump is required for the recirculation circuit 480.
In this example, the free-floating media 190 are also prevented from leaving the aerobic bioreactor 420 and from being transported via recirculation circuit 480 to the reservoir 452, at least during operation of the system 400. For this purpose the aerobic bioreactor 420 comprises suitable mechanical filters or screens 489 at the bioreactor outlet 427 and also at the bioreactor inlet 428, that prevent passage of the media 190 therethrough, while allowing flow of the liquid medium L therethrough. Alternatively, free-floating media 190 can be replaced with fixed media as in the first example of system 100, mutatis mutandis and no such filters or screens are necessary and can be omitted.
System 400 also comprises a waste inlet 432 opening directly into the aerobic bioreactor 420, and controllable via valve 435, and a processed effluent outlet 434, which in this example is provided in the reservoir 452, and is controllable via valve 431. For example, valves 435 and 431 can be motorized valves, the operation of which is controlled manually and/or via an automated controller, for example electronic control, computer control, hydraulic control, and so on.
Operation of the system 400 in BM is as disclosed above for the first example of system 100 optionally including preprocessing and/or post-processing, mutatis mutandis, with the main difference being that the respective flow rate T2 of recirculating flow of liquid medium L between the reservoir 452 and the aerobic bioreactor 420, is controlled by the flow rate of the liquid medium L around the channel 469.
In yet other alternative variations of the above first, second, third, or fourth examples, and alternative variations thereof, the algae is replaced with any other photosynthetic eukaryotic microorganisms or photosynthetic prokaryotic microorganisms, mutatis mutandis, for example as listed above.
Referring to FIGS. 5( a) and 5(b), a system for aerobic processing of waste, in particular liquid waste, according to a fifth example of the presently disclosed subject matter, generally designated 500, comprises an aerobic bioreactor 520 and an oxygen-rich liquid medium source 550, similar to aerobic bioreactor 120 and oxygen-rich liquid medium source 150, mutatis mutandis, but with some differences as will become clearer below.
Aerobic bioreactor 520 comprises a vessel 522 and is configured for aerobically processing waste therein using suitable microorganisms and oxygen, the oxygen being provided via a supply of oxygen-rich liquid medium L that is selectively and controllably recirculated between the liquid medium source 550 and the aerobic bioreactor 520.
Vessel 522 comprises lateral walls 524 and bottom base 523, and defines an internal volume 526 (for example, of magnitude V1), the respective aerobic processing volume. While the vessel 522 can have any desired or suitable shape, in this example vessel 522 is cylindrical, and in any case is configured for preventing the internal volume 526 from being irradiated by light, as disclosed for the first example, mutatis mutandis.
The system 500, in particular the bioreactor 520, further comprises an influent inlet (also referred to as waste inlet) 532 (optionally including a valve, not shown, and/or pump 533) at the aerobic bioreactor 520 for receiving waste into the internal volume 526 and that is to be treated aerobically by the system 500. The system 500, in particular the bioreactor 520, also comprises a treated effluent outlet 534 with valve 531, for dispensing treated effluent that results from aerobically treating the waste that is supplied to the aerobic bioreactor 520. In this example, the effluent outlet 534 is provided at the aerobic bioreactor 520; in alternative variations of this example the effluent outlet 534 can instead be provided at oxygen-rich liquid medium source 550.
The influent inlet 532 is located at a lower part of the vessel 522, and a plurality of conduits 538 branch out from influent inlet 532 to overlay the bottom base 523, and are fixed in the vessel 522 in vertical spaced relationship with the bottom base 523. The conduits 538 can be arranged to provide a grid-like pattern, for example, have openings 539 that allow influent, at an influent flow rate, to selectively enter internal volume 526 via influent inlet 532 and conduits 538. In this example, the openings 539 are distributed uniformly over the base 523, providing full coverage with respect to the bottom base 523, thereby allowing influent to be evenly distributed over the transverse cross section of the vessel 522.
The bioreactor 520 further comprises a clarifier vessel 562 located at the top of the vessel 522 and in fluid communication with the internal volume 526. The clarifier vessel 562 has a transverse cross-sectional area that increases in the upwards direction, and in this example, the clarifier vessel 562 has a frusto-conical outer wall 565 defining a clarifying volume 566. The clarifier vessel 562 has a bottom rim 561 that is sealingly fixed to an upper portion 535 of vessel 522 below the upper rim 579 of the vessel 522. A sludge collection channel 537 is formed between the outside of upper portion 535 and the inside of frusto-conical wall 565 (for example having half angle θ of 55°), allowing sludge to accumulate therein, and which can be removed therefrom. However, in alternative variations of this example, the bottom rim 561 can instead be sealingly fixed directly to the upper rim 579 of the vessel 522, for example.
The liquid medium source 550 comprises reservoir 552, for example similar to liquid medium source 150 and reservoir 152 of the first example or the liquid medium source and reservoir of the other examples disclosed herein or any other suitable configuration, mutatis mutandis, and is configured for providing a supply of liquid medium L that is controllably recirculated between the reservoir 552 and the aerobic bioreactor 520.
As with other examples disclosed herein, the reservoir 552 is different from and/or separate from the aerobic bioreactor 520, and defines an internal volume 556 (for example, of magnitude V2), the respective reservoir algae growth volume. The internal volume 556 is different from and separate from the internal volume 526 of the aerobic bioreactor 520, and reservoir 552 is configured for allowing the internal volume 556 to be irradiated by light.
For example, the reservoir 552 is concentrically defined around the aerobic bioreactor 520, in the form of a horizontal endless loop, for example an annular raceway, and an upper rim 563 of clarifier 562 separates internal volume 556 from the internal volumes 526 and 566. For example, a driving device (not shown) is provided for providing motion to the liquid medium L in internal volume 556 of reservoir 552. For example, the driving device can comprise a powered paddling device mounted to the reservoir 552, for example similar to the paddling device as disclosed above for other examples, mutatis mutandis.
Optionally, the reservoir 552 comprises suitable mechanical filters, screens or other selective barriers (not shown) at the reservoir outlet, and/or at the reservoir inlet, that prevent passage of the media 190 therethrough, while allowing flow of the liquid medium L therethrough.
System 500 comprises a recirculation circuit 580, having a reservoir outward flow path 581 and a reservoir return flow path 583 for providing a recirculating flow through the aerobic bioreactor 520, and in particular for recirculating the liquid medium L between the aerobic bioreactor 520 and the reservoir 550, in particular between the internal volume 526 and the internal volume 556.
The reservoir outward flow path 581 is provided by conduit 584, which provides fluid communication, in particular liquid communication, between bioreactor inlet 528 and reservoir outlet 558, and in particular, to allow flow of liquid from the reservoir 550 to the aerobic bioreactor 520.
The bioreactor inlet 528 is located at a lower part of the vessel 522, and a plurality of conduits 529 branch out from bioreactor inlet 528 to overlay the base bottom base 523. The conduits 529 are fixed in the vessel 522 in vertical spaced relationship with the base bottom base 523. The conduits 529 can be arranged to provide a grid-like pattern, for example, having openings 588 that allow fluid from the reservoir 550 to selectively enter internal volume 526 via bioreactor inlet 528 and conduits 529. In this example, the openings 588 are distributed uniformly over the base 523, providing full coverage with respect to the bottom base 523, thereby allowing oxygen, substrates and so on in the liquid medium L to be evenly distributed over the transverse cross section of the vessel 522.
The reservoir return flow path 583 provides fluid communication, in particular liquid communication, between bioreactor outlet 527 and reservoir inlet 557, and in particular, to allow flow of liquid mixture Q from the aerobic bioreactor 520 to the reservoir 550. The liquid mixture Q includes one or more of liquid medium L, waste W, and processed effluent E in varying proportions, and the relative proportions of liquid medium L, waste W, and processed effluent E in liquid mixture Q can be different in different parts of the system 500 and/or can vary during operation of the system 500.
In this example, the bioreactor outlet 527 and reservoir inlet 557 are defined by upper rim 563 of clarifier vessel 562, which functions as a weir allowing liquid from the bioreactor 520 to overflow into the reservoir 550. In alternative variations of this example, reservoir return flow path 583 is provided by a conduit which thus provides fluid communication, in particular liquid communication, between a suitable bioreactor outlet and a suitable reservoir inlet.
In this example, the recirculation circuit 580 further comprises a pump 585 for driving the aforesaid recirculation of the liquid medium L between the aerobic bioreactor 520 and the reservoir 550. For example, such a pump 585 can be similar to pump 185, mutatis mutandis.
Thus, in operation, flow of liquid medium L along the reservoir outward flow path 581 is via powered pump 585 which forces the flow of liquid medium L through the bioreactor 520 in a generally upward direction, i.e., in a direction generally opposed to gravity, through the vessel 522, while in the reservoir return flow path 583, flow of liquid medium L is via gravity.
The bioreactor 520 is designed to provide a desired upward flow velocity within the vessel 522, for example 3 meters per hour, and to provide a suitable hydraulic retention time (HRT), for example 1 to 2 hours, for the fluids in the internal volume 526. For a given magnitude V1 of the internal volume 526, and a given volume flow rate through this volume, the average velocity of the flow through the internal volume 526 can be modified by changing one or both of the height of the vessel 522 and the transverse cross-sectional area thereof. For example, the average velocity of the flow through the internal volume 526 can be increased, by increasing the height of the vessel 522 and/or decreasing the transverse cross-sectional area thereof. For example, the average velocity of the flow through the internal volume 526 can be decreased, by decreasing the height of the vessel 522 and/or increasing the transverse cross-sectional area thereof.
As in the other examples disclosed herein, mutatis mutandis, the liquid medium source 550, in particular the reservoir 552, is configured for generating and providing oxygen to liquid medium L, so that the oxygen-rich liquid medium L can be provided to the aerobic bioreactor 520 (via conduit 584), and the generation of oxygen is accomplished in a similar manner, i.e., by the photosynthetic action of photosynthetic microorganisms, in particular photosynthetic eukaryotic or prokaryotic microorganisms for example algae, (that are carried in the liquid medium L), when illuminated by said light and provided with appropriate nutrients.
As already mentioned, the aerobic bioreactor 520 is configured for aerobically processing waste using suitable microorganisms and oxygen provided by oxygen-rich liquid medium L, for example as disclosed herein for the first example or other examples, mutatis mutandis.
In this example, the microorganisms are fixed on media 190, as disclosed above in other examples of the system, mutatis mutandis.
In this example, the media 190 are mobile, i.e. free-floating media, configured for moving within the liquid mixture Q in the internal volume 526, the liquid mixture Q including liquid medium L, waste W, and processed effluent E in varying proportions during operation of the system 500.
In this example, all or a portion (for example a majority) of the media 190 have a specific gravity that is greater than that of the liquid mixture Q, or at least of the liquid medium L, for example 1.05 g/ml, and thus in the absence of an upwards flow of liquid within the vessel 522, the media 190 would tend to settle at the bottom of the vessel 522. Optionally, some of the media 190 can be provided having a specific gravity that is less than or equal to that of the liquid mixture Q, or at least of the liquid medium L, for example 0.95 g/ml or 1.05 g/ml, respectively, and such media mixes with other media 190 having specific gravity that is greater than that of the liquid mixture Q, or of the liquid medium L, in operation of the aerobic bioreactor 520.
In this example, the free-floating media 190 are prevented from leaving the aerobic bioreactor 520 and from being transported via recirculation circuit 580 to the reservoir 552, at least during operation of the system 500. For this purpose the aerobic bioreactor 520 can be operated to provide an upward flow rate and/or upward velocity through the vessel 522 sufficiently high on the one hand to have the effect of providing a fluidized bed type effect to the media 190, such that the media 190 remain generally suspended within the internal volume 526. By generally suspended is meant that the media 190 can move around within the internal volume 526, the upward flow rate and/or upward velocity through the vessel 522 ensuring that the media 190 take mean positions somewhere intermediate between the bottom base and the top of vessel 522, but on the other hand the upward flow rate and/or upward velocity through the vessel 522 not being so high such as to cause the media 190, or a significant portion of the media 190 to maintain mean positions close to the top of vessel 522, and possibly spill over onto the reservoir 552 via the clarifier vessel 562.
The widening cross-section of the clarifier vessel 562 significantly reduces the velocity of the fluid flowing through the bioreactor 520 at the clarifier vessel 562, as compared with the flow velocity in the vessel 522. This has the effect of “clarifying” the fluid, i.e., allowing separation of the media 190, as well as other solids, that can now flow downwards in the vessel 522.
A suitable filter (not shown), such as for example a rotating cloth filter, is provided to separate the effluent from the clarified effluent, which can be selectively removed via to treated effluent outlet 534.
Optionally, the aerobic bioreactor 520 comprises suitable mechanical filters, screens or other selective barriers (not shown) at the bioreactor outlet 527, and/or at the bioreactor inlet 528, that prevent passage of the media 190 therethrough, while allowing flow of the liquid medium L therethrough.
Optionally, the media 190 can also additionally comprise fixed media, i.e., a portion of the media is affixed in situ with respect to the location thereof within the internal volume 526, i.e., a portion of the media is fixed in situ within the bioreactor
In this example, the upward flow through the aerobic bioreactor 520 provides mixing of the media 190 within the liquid mixture Q, while minimizing or preventing damage to the media 190. This arrangement does away with the need for a mechanical mixer for the system 500, and can reduce the power requirements of the system 500 significantly. For example, some mechanical mixers can consume electrical power at a rate of about 25 W/m³of the volume being mixed, and such power consumption can be saved with the current arrangement, for example. Nevertheless, in alternative variations of this example, the aerobic bioreactor 520 further comprises a mixing device, configured for mixing the media 190 within the liquid mixture Q, while minimizing or preventing damage to the media 190, for example including the mixing device as disclosed above for other examples, mutatis mutandis.
Optionally, the system 500 can further comprise an auxiliary aeration system (not shown) configured for selectively providing gaseous oxygen or air to the aerobic bioreactor 520, and/or an auxiliary CO₂system configured for selectively providing gaseous carbon dioxide or carbon-dioxide rich air to the liquid source 550, for example as disclosed for the first example or other examples, mutatis mutandis.
In an alternative variation of the fifth example, and referring to FIG. 6, the respective bottom base 523′ is configured for sludge collection, and comprises a conical or frusto-conical wall 565′ (for example at half angle φ of 55°), allowing sludge to accumulate therein, and which can be removed therefrom via conduit and pump 560′. Thus, solids which settle below the conduits 528, 538, in the feed cycle and/or in the sedimentation stage, can be collected in bottom base 523′ and removed therefrom as desired.
When only influent is flowing into the vessel 522 (with no recirculation flow via recirculation circuit 580), the media 190 are embedded or engulfed in an environment that is low in dissolved oxygen (DO), and high in biochemical oxygen demand (BOD). Filtered chemical oxygen demand (CODf) uptake occurs in anaerobic conditions. The media 190 becomes saturated in organic material quantified as chemical oxygen demand (COD) as diffusion resistance is reduced to the existing high concentration gradient in the vessel 522. On the other hand, when recirculation flow is provided to the aerobic bioreactor 520 via recirculation circuit 580, for example at flow rates between 400% and 600% of the influent flow rate, this provides high dissolved oxygen concentrations and dramatically dilutes COD levels, allowing the media 190 to be exposed to aerobic conditions, and thereby significantly improves the efficiency of the aerobic bioreactor 520.
It is to be noted that the aerobic bioreactor 520 can be provided as a stand alone unit, that is selectively connectable to any suitable liquid medium source, for example liquid medium source 550 or any stand alone liquid medium source, and that is selectively connectable to any source of liquid waste.
Operation of system 500 in batch mode (BM), is for example as follows.
Referring to FIGS. 7( a) to 7(c), waste W, mainly in liquid form, is conveyed to the aerobic bioreactor 520 at an effluent flow rate T1 via waste inlet 532, for a period of time, such that a particular volume of waste W is introduced into the vessel 522. For example, such a volume of waste W can be sufficient to reach a part of the height of the vessel 522, for example to cover media 190, that is mainly suspended in the lower part of the vessel 522.
Optionally, the waste W is first subjected to preprocessing, including a screening and degritting process to remove solids, with or without a preliminary anaerobic treatment process, prior to being fed to the aerobic bioreactor 520.
If the aerobic bioreactor 520 is already filled up to or close to the rim 563, liquid in the upper part of the aerobic bioreactor 520 is displaced out of the aerobic bioreactor 520 via the effluent outlet 534. For example, if this batch of waste water W is being processed after the completion of processing of a previously batch still in the aerobic bioreactor 520, then effluent E is displaced out of the aerobic bioreactor 520 via the effluent outlet 534 concurrently with a new batch of waste W being introduced into the vessel 522 via waste inlet 532.
The waste input is then turned off at waste inlet 532, and the effluent outlet 534 is also closed. The liquid medium source 550 is operated to provide a flow rate of liquid medium L through aerobic bioreactor 520, providing oxygen to the aerobic bioreactor 520, and allowing the aerobic bioreactor 520 and the liquid medium source 550 to each operate under its own optimal conditions, but without continuous addition of waste W or dispensing of effluent E.
In particular, and referring to FIG. 8, there is provided a recirculating flow of liquid medium L between the reservoir 552 and the aerobic bioreactor 520 via recirculation circuit 580. In practice there is a recirculating flow of liquid mixture Q, including a high proportion of liquid medium L, between the reservoir 552 and the aerobic bioreactor 520 via recirculation circuit 580, at a flow rate T2.
For example, flow rate T2 can be 5 or 6 times greater than effluent flow rate T1. In practice the liquid medium L also carries algae to and from the reservoir 552 via recirculation circuit 580. The liquid medium L in reservoir 552 is being continuously provided with oxygen generated by the algae therein as the liquid medium L is exposed to said light and provided with nutrients, and this oxygen generation process is enhanced by forcing the liquid medium L to flow around reservoir 552 by the action of a suitable driver. Thus, the liquid medium L delivered to the aerobic bioreactor 520 via conduit 584 is oxygen-rich. At the same time, CO₂that is produced by bacteria is transferred to the liquid mixture Q, including liquid medium L, providing carbon for algal growth.
The microorganisms fixed in media 190 treat the waste aerobically for example by digesting or decomposing the waste, using oxygen dissolved in the liquid medium L delivered from the reservoir 552, thereby converting the waste W into processed effluent E.
As the recirculation flow enters the vessel 522 via the bottom part thereof and flows in an upwards direction through the vessel 522 at a relatively high velocity, the media 190, in particular the media that is heavier than the density of the upflowing liquid mixture Q, become fluidized and become well mixed in the upflowing liquid mixture Q, enhancing the aerobic processing of the waste W. As the recirculation flow reaches the upper part of the vessel 522 and then through the clarifier vessel 561 of waste W, the flow velocity is significantly reduced. This essentially results in the media 190 remaining the vessel 522 and providing a clarified essentially media free liquid mixture Q in the clarifier vessel 561. Concurrently, solids and other sludge can collect at the sludge collection channel 537, and recirculating flow overflows from rim 563 into the reservoir 552.
In practice, a particular mixture M1 of the processed effluent E, (partially de-oxygenized) liquid medium L, and possibly waste W, in varying proportions, in the liquid mixture Q leaves the aerobic bioreactor 520 via conduit 582. Similarly, a mixture M2 of the processed effluent E, (oxygen-rich) liquid medium L, and possibly waste W, in varying proportions, of liquid mixture Q recirculates back and enters the aerobic bioreactor 520 via conduit 584.
Recirculation of liquid mixture Q via recirculation circuit 580 continues for a number of recirculation cycles, or for as long as desired. Typically, when all or most of the waste is processed, the processed effluent can be drained from the aerobic bioreactor 520 through the effluent outlet 534, though in practice such effluent can be mixed in with a proportion of liquid medium L, and/or possibly with a proportion of waste W.
Similarly, in practice, a particular mixture M3 of the processed effluent E, liquid medium L, and possibly waste W, in varying proportions, of liquid mixture Q can be dispensed via the dispensing outlet 534.
Thus, in operation of the system 500, and as with other examples disclosed above, mutatis mutandis, the microorganisms aerobically treat the waste W in internal volume 526 and in the absence of said light, i.e., in darkened conditions, which are optimal for the microorganisms, while being provided with ample oxygen dissolved in the liquid medium L. In the darkened conditions provided by the aerobic bioreactor 520, the algae that can be recirculating through the aerobic bioreactor 520 are thus under conditions that do not promote further growth, and thus minimize interference with the aerobic processing of the waste by the microorganisms. Furthermore, the provision of the microorganism as a biofilm fixed on media 190, in which the microorganism are exposed to the waste W and oxygen-rich liquid medium L over a large surface area relative to the volume occupied by the media 190, enables the waste W to be processed faster and more efficiently than would be the case if the microorganism were instead provided as a sludge moving throughout the system, for example. Furthermore, by creating fluidized bed-type conditions for the media 190 energy requirements for mixing the media can be reduced or eliminated, while concurrently providing efficient mixing of the media with the oxygen rich liquid, and optimizing conditions for aerobic processing of the waste, as compared with not providing fluidized bed conditions for the media 190. The energy requirements for operating the system 500 are thus relatively modest. Optionally, however, a mechanical mixer can be selectively used as desired to further improve mixing, at an energy cost.
On the other hand, the conditions for generating oxygen by the algae in source 550 are also concurrently optimal, the algae receiving said light and nutrients in the reservoir 552, and preferably kept in motion around the reservoir 552. Further, these conditions are further optimized by the relative absence of the microorganisms in the reservoir 552, since the microorganisms, being fixed on the media 190, are prevented from being transported to the reservoir 552 from the aerobic bioreactor 520.
Thus, the aerobic treatment process of waste is independent and separated from the process of generating oxygen via algae, avoiding or minimizing interference between the two processes, and each process can be separately and independently optimized.
For a given requirement of throughput of waste through the aerobic bioreactor 520, the reservoir 552 can be sized accordingly whereby to provide the necessary oxygen demand for the bioreactor 520.
The system 500 can optionally further comprise post-processing systems for post-processing the effluent E. For example, downstream of effluent outlet 134 can be provided further filters and purifiers to further purify the effluent E. For example, a plurality of systems 100 can be connected in series, with the first one receiving waste W, and having its effluent outlet 534 connected to the waste inlet 532 of the next system 500 (thus the effluent from the first system is considered as the “waste” being supplied to the next system), which is similarly connected to the next system, and so on, the last system 100 then dispensing the many-times processed effluent E.
It is to be noted that the aerobic processing of the waste in the aerobic bioreactor 520 generates CO₂as a byproduct, and this CO₂can be routed to the reservoir 552 (via suitable piping or the existing liquid flows, for example) to provide additional carbon to the algae therein. Alternatively, the biogas itself, which is rich in CO₂, can be used to enrich the algae with a carbon source by injecting it through the liquid medium L. Thus, the waste processing system 500 and the corresponding waste processing method can be considered to be concurrently, or alternatively, a system and method, respectively, for the production of algae, in which the algae can be harvested from the respective source of oxygen-rich liquid medium, and the bioreactor generates the carbon necessary for the algal growth.
It is also to be noted that in the aforementioned preprocessing in the form of said anaerobic treatment process, biogas can be generated. This biogas can be sold off, or can be utilized for power generation, for example for powering the system 500, and the CO₂produced as a byproduct of said power generation can also be routed to the reservoir 152 via suitable piping for example to provide additional nutrients to the algae therein.
Once a batch of effluent is ready to be removed from the system, a new batch of waste W can be provided to the system 500 for processing.
Referring to FIG. 9, the system 500 can be operated according to a settle cycle when desired. No waste is provided at waste inlet 532, and no effluent is removed via the effluent outlet 534. Furthermore, there is no recirculation flow provided by the recirculation circuit 580. Under these conditions, solids in the liquid medium settle below the conduits 538 and 529, and can be removed, for example with the arrangement illustrated in FIG. 6. It is to be noted that a suitable mechanical arrangement, for example a mesh, can be provided in the vicinity of the conduits 538 and 529, for example just above the conduits 538 and 529, to prevent the media 190 from settling at the bottom of the vessel 522 with other unwanted solids.
Alternatively, system 500 can be operated in a continuous flow mode (CFM), for example as follows. Waste W (after the aforesaid preprocessing) is provided to the aerobic bioreactor 520 continuously, and the recirculation circuit continually provides recirculation flow. The microorganisms that are fixed on media 190 aerobically process the waste in a similar to that of the BM disclosed above, mutatis mutandis, typically by digesting or decomposing the waste, and the processed effluent can be drained from the aerobic bioreactor 520 (or optionally via the reservoir 552) in a continuous manner. Similar to the CFM mode for the first example disclosed above, mutatis mutandis, the system 500 is also set up such that in steady-state operating conditions, mixture M1 of the liquid mixture Q (i.e., of the processed effluent E, (partially de-oxygenized) liquid medium L, and possibly waste W, that leaves the aerobic bioreactor 520 via conduit 582) has a high proportion of effluent E relative to waste W, mixture M2 (of the processed effluent E, (oxygen-rich) liquid medium L, and possibly waste W, that circulates back and enters the aerobic bioreactor 520 via conduit 584) has a high proportion of liquid medium L relative to waste W or effluent E, and mixture M3 of the liquid mixture Q (i.e., of the processed effluent E, liquid medium L, and possibly waste W, that is dispensed via the dispensing outlet 534) has a high proportion of effluent E relative to waste W.
Referring to FIG. 10, the aerobic bioreactor 520 can optionally be modified as follows. One or more draft tubes 570 are provided in the vessel 522. Each draft tube 570 is laterally spaced from the lateral walls 524 of the vessel 522, and each said draft tube 570 provides an initially decreasing flow area in the direction of flow therethrough. For example, each draft tube 570 comprises an inlet flared portion, joined to an exit flared portion via a linear portion. The inlet flared portion is in the form of an inlet funnel 572 having an inlet rim 572 a and a throat 572 b, the inlet rim 572 a defining a larger cross-sectional inlet area than the throat 572 b. The outlet flared portion is in the form of an outlet funnel 574 having an outlet rim 574 a and a throat 574 b, the outlet rim 574 a defining a larger cross-sectional inlet area than the throat 574 b. the linear portion is in the form of a generally vertical cylindrical tube 573 joined at a lower end thereof to throat 572 b, and at an upper end thereof to throat 574 b. Furthermore, the bioreactor inlet 528 is located at a lower part of the vessel 522, and the plurality of conduits 529 branch out from bioreactor inlet 528 to overlay the base bottom base 523, and are fixed in the vessel 522 in vertical spaced relationship with the base bottom base 523. The conduits 529 can be arranged to provide a grid-like pattern, for example, having openings 588 that allow fluid from the reservoir 552 to selectively enter internal volume 526 via bioreactor inlet 528 and conduits 529. However, in the example of FIG. 10, the openings 588 are distributed uniformly over parts of the base 523 such that they are facing a respective inlet funnel 572, thereby facilitating oxygen, substrates and so on in the liquid medium Q, in particular in the liquid medium L, to be channeled through the draft tubes 570. In operation of the recirculation circuit 580, fluid recirculated via recirculation circuit 580 and provided to the vessel 522 via the openings 588 is channeled through draft tubes 570 at a relatively higher velocity than in the absence of the draft tubes 570, further enhancing mixing of the media 190, and furthermore, a recirculation flow field C is set up within the vessel 520, with liquid flowing in a downward direction B within the vessel 522 on the outside of the draft tubes 570. Optionally, but not necessarily, the openings 539 are also distributed uniformly over parts of the base 523 such that they are facing a respective inlet funnel 572, thereby facilitating waste W to be channeled therefrom through the draft tubes 570. The modified bioreactor 520 of FIG. 10 can be operated in batch mode or continuous flow mode in a similar manner to that disclosed above with respect to FIGS. 7( a) to 9, mutatis mutandis.
Referring to FIG. 11, the aerobic bioreactor 520 of FIGS. 5( a) to 9 can optionally be modified as follows. One or more draft tubes 570 are provided in the vessel 522, similar to the draft tubes of FIG. 10, but inverted, such that the inlet flared portion is now vertically above the exit flared portion. Thus, inlet funnel 572 is now above the generally vertical cylindrical tube 573, while the outlet funnel 574 is now above the generally vertical cylindrical tube 573. Furthermore, the bioreactor inlet 528 is now located at an upper part of the vessel 522, above the draft tubes 570, and the plurality of conduits 529 that branch out from bioreactor inlet 528 are fixed in the vessel 522 in vertical spaced relationship with the base bottom base 523, but close to the upper rim 579. The conduits 529 are arranged to provide a grid-like pattern, for example, with openings 588 that allow fluid from the reservoir 552 to selectively enter internal volume 526 via bioreactor inlet 528 and conduits 529. However, in the example of FIG. 11, the openings 588 are facing a respective inlet funnel 572, thereby facilitating oxygen, substrates and so on in the liquid medium L to be channeled through the draft tubes 570, but in a downward direction. In operation of the respective recirculation circuit 580, fluid recirculated via recirculation circuit 580 and provided to the vessel 522 via the openings 588 is channeled in a downwards direction through draft tubes 570, and also at a relatively higher velocity than in the absence of the draft tubes 570. In this example, at least a portion of the media 190, for a example a majority of or all the media 190, have a specific gravity that is less than that of the liquid mixture Q, or at least of the liquid medium L, for example 0.95 g/ml, and such media can be mixed with other media 190 having specific gravity that is greater than or equal to that of the liquid mixture Q, or of the liquid medium L, for example 1.05 g/ml or 1.0 g/ml, respectively, in operation of the aerobic bioreactor 520 of FIG. 11. This arrangement also enhances mixing of the media 190, and furthermore, a recirculation flow field C′ is set up within the vessel 520, with liquid flowing in an upward direction B′ within the vessel 522 on the outside of the draft tubes 570. Thus, the media 190 that have a density less than that of the liquid mixture Q, or at least of the liquid medium L, tend to float upwards along direction B′ and re-enter the draft tubes 570 via the upper inlet flared portion due to the recirculation flow field C′.
In the example of FIG. 11, the influent inlet 532 is now located at an upper part of the vessel 522, above the draft tubes 570, and the plurality of conduits 538 branch out from influent inlet 532 are fixed in the vessel 522 in vertical spaced relationship with the base bottom base 523, but close to the upper rim 579. The conduits 538 are arranged to provide a grid-like pattern, for example, with openings 539 that allow influent to selectively enter internal volume 526 via influent inlet 532 and conduits 538. Furthermore, in the example of FIG. 11, the openings 539 are facing a respective inlet funnel 572, thereby facilitating the waste W to be channeled through the draft tubes 570, in a downward direction. It is to be noted that is the example of FIG. 11 is to be run in batch mode only, and not in continuous flow mode, the influent inlet 532, conduits 538 and openings 539 can be arranged as disclosed for the examples illustrated in FIGS. 5( a) to 10, mutatis mutandis, below the draft tubes 570. The modified bioreactor 520 of FIG. 11 shows the treated effluent outlet 534 (with valve 531) provided at the vessel 522, and the portion of the treated effluent outlet 534 that projects into internal volume 526 can comprise a discharge screen, for example.
The modified bioreactor 520 of FIG. 11 can be operated in batch mode or continuous flow mode in a similar manner to the batch mode BM or continuous flow mode CFM, respectively, as disclosed above with respect to FIGS. 7( a) to 10, mutatis mutandis, with some main differences as follows. In batch mode or in continuous flow mode, the liquid provided by the recirculation circuit 580 now provides a generally downward flow through the draft tubes 570, and effluent is collected from the region between the outside of draft tubes 570 and the lateral walls 524. In continuous flow mode the waste influent W is also provided to the internal volume, in particular towards the draft tubes 570, in a downwards direction therethrough. In batch mode the waste influent W is also provided to the internal volume, in any direction, for example in an upwards or a downwards direction therethrough.
It is to be noted that the feature of providing a fluidized bed conditions in the system according to the examples of FIG. 5( a) through to FIG. 11, can be applied in a similar manner, mutatis mutandis, to one or more of the systems according to the examples illustrated in FIGS. 1 to 4.
In the method claims that follow, alphanumeric characters and Roman numerals used to designate claim steps are provided for convenience only and do not imply any particular order of performing the steps.
Finally, it should be noted that the word “comprising” as used throughout the appended claims is to be interpreted to mean “including but not limited to”.
While there has been shown and disclosed examples in accordance with the presently disclosed subject matter, it will be appreciated that many changes may be made therein without departing from the spirit of the presently disclosed subject matter.

Claims

1. System for aerobically processing waste, comprising:

an aerobic bioreactor configured for aerobically processing waste via bacteria fixed on media to provide processed effluent from the waste;

a source of oxygen-rich liquid medium, said source being different from said aerobic bioreactor, said source being in selective fluid communication with said aerobic bioreactor.

2. System according to claim 1, comprising a recirculation circuit configured for controllably recirculating said liquid medium between said aerobic bioreactor and said source.

3. System according to claim 1 or claim 2, wherein said system is configured for preventing the media from being transferred from the aerobic bioreactor to said source.

4. System according to any one of claims 1 to 3, wherein said media is restricted to a confined volume within said aerobic bioreactor.

5. System according to any one of claims 1 to 4, wherein in operation of the system a flow of said oxygen-rich liquid medium is forced through said confined volume wherein to interact with said bacteria.

6. System for aerobically processing waste, comprising:

an aerobic bioreactor configured for aerobically processing waste to provide processed effluent from the waste;

a source of oxygen-rich liquid medium, said source being different from the bioreactor,

a recirculation circuit configured for controllably recirculating said liquid medium between said aerobic bioreactor and said source.

7. System according to claim 6, wherein said aerobic bioreactor is configured for aerobically processing waste via bacteria fixed on media.

8. System according to claim 7, wherein said system is configured for preventing the media from being transferred from the aerobic bioreactor to the source.

9. System according to any one of claims 7 to 8, wherein said media is restricted to a confined volume within said aerobic bioreactor.

10. System according to claim 9, wherein in operation of the system a flow of said oxygen-rich liquid medium is forced through said confined volume wherein to interact with said bacteria.

11. System for aerobically processing waste, comprising:

bacteria for aerobically processing waste to provide processed effluent from the waste, said bacteria being fixed on media restricted to a confined volume;

a flow of oxygen-rich liquid medium forced through said confined volume wherein to interact with said bacteria.

12. System according to claim 11, wherein said confined volume is provided in an aerobic bioreactor, and wherein a source of oxygen-rich liquid medium provides said flow of oxygen-rich medium, said source being different from the aerobic bioreactor.

13. System according to claim 12, wherein said system is configured for preventing the media from being transferred from the aerobic bioreactor to the source.

14. System according to claim 12 or claim 13, comprising a recirculation circuit configured for controllably recirculating said liquid medium between said aerobic bioreactor and said source.

15. System according to any one of claims 1 to 14, wherein said source comprises photosynthetic microorganisms that generate oxygen to said liquid medium responsive to exposure to light.

16. System according to any one of claims 1 to 15, wherein said source comprises any one of photosynthetic eukaryotic microorganisms and photosynthetic prokaryotic microorganisms that generate oxygen to said liquid medium responsive to exposure to light.

17. System according to any one of claims 1 to 16, wherein said source comprises algae that generate oxygen to said liquid medium responsive to exposure to light.

18. System according to any one of claims 15 to 17, wherein said photosynthetic microorganisms comprise at least one of: Chlorella spp, spirulina, scendesmus, or any other photosynthetic microalgae or cyanobacteria.

19. System according to any one of claims 1 to 18, wherein said source comprises a reservoir comprising a channel therein defining a reservoir internal volume, and configured for driving said liquid medium around said channel in operation of the system.

20. System according to any one of claims 1 to 19, further comprising an auxiliary aeration system, configured for selectively providing gaseous oxygen or air to said bioreactor.

21. System according to any one of claims 1 to 20, further comprising an auxiliary CO₂system, configured for selectively providing carbon dioxide to said source.

22. System according to any one of claims 1 to 21, wherein said media is fixed in situ within the bioreactor.

23. System according to any one of claims 1 to 22, wherein said media is mobile within the bioreactor.

24. System according to any one of claims 1 to 23, wherein said media comprise biofilm carrier elements, in the form of solid inert substrates having a relatively large surface area to volume ratio.

25. System according to any one of claims 1 to 24, comprising a waste inlet configured for receiving the waste and a dispensing outlet for dispensing treated effluent, and wherein

said bioreactor comprises at least one vessel defining a respective aerobic processing volume, the at least one vessel comprising a bioreactor fluid medium inlet and a bioreactor fluid medium outlet, each in selective fluid communication with said source, the at least one vessel being configured for ensuring that the respective aerobic processing volume is partially or fully shielded from light at least during operation of the system;

said source comprises at least one reservoir defining a respective reservoir volume for accommodating a volume of said liquid medium, and further comprising a source fluid medium inlet and a source fluid medium outlet, each in selective fluid communication with said aerobic bioreactor, and a driving device for providing motion to said liquid medium within said respective reservoir volume, the at least one reservoir being configured for ensuring that the respective reservoir volume is exposed to light at least during operation of said source wherein to provide said oxygen-rich liquid medium.

26. System according to claim 25, wherein said driving device comprises a powered paddling device mounted to the respective said reservoir.

27. System according to claim 25 or claim 26, wherein said at least one reservoir comprises at least one flow channel in the form of a horizontal endless loop.

28. System according to claim 27, wherein said at least one flow channel has an annular plan form.

29. System according to claim 27, wherein said at least one flow channel has a raceway configuration.

30. System according to any one of claims 25 to 29, wherein said source fluid medium outlet is configured for preventing outflow of said media therethrough.

31. System according to any one of claims 25 to 30, comprising:

at least one set of conduits providing said fluid communication between said at least one said vessel and a respective said reservoir;

a pumping system, different from said driving device, for providing recirculation of said medium between said at least one vessel and the respective said reservoir through said set of conduits.

32. System according to claim 31, wherein one said conduit connects said source fluid medium inlet with said bioreactor fluid medium outlet and wherein another said conduit connects said source fluid medium outlet with said bioreactor fluid medium inlet.

33. System according to any one of claims 1 to 32, wherein said waste is aerobically treatable for removing pollutants therefrom.

34. System according to any one of claims 1 to 33, wherein said waste is a liquid waste.

35. System according to any one of claims 1 to 34, wherein said waste comprises waste water.

36. System according to any one of claims 1 to 35, wherein said waste includes organic types of waste.

37. System according to any one of claims 1 to 36, wherein said waste comprises at least one of animal, agricultural, industrial or human waste transported in water or another liquid medium.

38. System according to any one of claims 1 to 37, wherein said bioreactor is configured for providing a through-flow of at least the oxygen-rich liquid medium through the bioreactor at a predetermined velocity, wherein said predetermined velocity is sufficient to cause the media therein to expand within the bioreactor and to mix therein with at least the oxygen-rich liquid medium.

39. A method for aerobically processing waste, comprising:

aerobically reacting waste in an aerobic bioreactor via bacteria fixed on media;

providing oxygen-rich liquid medium to the bioreactor from an oxygen-rich liquid source, wherein the oxygen-rich liquid source is different from the bioreactor.

40. Method according to claim 39, further comprising controllably recirculating said liquid medium between said aerobic bioreactor and said oxygen-rich source.

41. Method according to claim 39 or claim 40, comprising preventing the media from being transferred from the aerobic bioreactor to said source.

42. Method according to any one of claims 39 to 41, wherein said media is restricted to a confined volume within said aerobic bioreactor.

43. Method according to claim 42, a flow of said oxygen-rich liquid medium is forced through said confined volume wherein to interact with said bacteria.

44. A method for aerobically processing waste, comprising:

aerobically processing waste in an aerobic bioreactor to provide processed effluent from the waste;

providing oxygen-rich liquid medium to the bioreactor from an oxygen-rich liquid source, wherein the oxygen-rich liquid source is different from the bioreactor,

controllably recirculating said liquid medium between said aerobic bioreactor and said source.

45. Method according to claim 44, wherein said aerobic bioreactor is configured for aerobically processing waste via bacteria fixed on media.

46. Method according to claim 45, comprising preventing the media from being transferred from the aerobic bioreactor to the oxygen-rich liquid source.

47. Method according to any one of claims 45 to 46, wherein said media is restricted to a confined volume within said aerobic bioreactor.

48. Method according to claim 47, wherein a flow of said oxygen-rich liquid medium is forced through said confined volume wherein to interact with said bacteria.

49. A method for aerobically processing waste, comprising:

aerobically processing waste with bacteria to provide processed effluent from the waste, said bacteria being fixed on media restricted to a confined volume;

forcing a flow of oxygen-rich liquid medium through said confined volume wherein to interact with said bacteria.

50. Method according to claim 49, wherein said confined volume is provided in an aerobic bioreactor, and wherein a source of oxygen-rich liquid medium provides said flow of oxygen-rich medium, said source being different from the aerobic bioreactor.

51. Method according to claim 50, comprising preventing the media from being transferred from the aerobic bioreactor to the source.

52. Method according to claim 50 or claim 51, comprising controllably recirculating said liquid medium between said aerobic bioreactor and said source.

53. Method according to any one of claims 39 to 52, wherein said liquid medium comprises photosynthetic microorganisms that generate and provide oxygen to said liquid medium responsive to exposure to light.

54. A method for aerobically processing waste, comprising:

reacting waste aerobically with bacteria in a bioreactor volume under conditions configured for inhibiting or reducing growth of photosynthetic microorganisms;

providing a flow of oxygen-producing photosynthetic microorganisms through the bioreactor volume from a source configured for promoting oxygen production by photosynthetic microorganisms, the source being different from the bioreactor volume, the photosynthetic microorganisms generating and providing oxygen to said liquid medium responsive to exposure to light; and

preventing at least a majority of the bacteria from exiting the bioreactor with said flow of photosynthetic microorganisms.

55. Method according to any one of claims 53 to 54, wherein said photosynthetic microorganisms comprise any one of photosynthetic eukaryotic microorganisms and photosynthetic prokaryotic microorganisms that generate oxygen to said liquid medium responsive to exposure to light.

56. Method according to any one of claims 53 to 55, wherein said source comprises algae that generate oxygen to said liquid medium responsive to exposure to light.

57. Method according to any one of claims 53 to 56, wherein said photosynthetic microorganisms comprise at least one of: Chlorella spp., spirulina, scendesmus, or any other photosynthetic microalgae or cyanobacteria.

58. Method according to any one of claims 39 to 57, wherein said waste is aerobically treatable for removing pollutants therefrom.

59. Method according to any one of claims 39 to 58, wherein said waste is a liquid waste.

60. Method according to any one of claims 39 to 59, wherein said waste comprises waste water and/or organic types of waste.

61. Method according to any one of claims 39 to 60, wherein said waste comprises at least one of animal, agricultural, industrial or human waste transported in water or another liquid medium.

62. Method according to any one of claims 39 to 61, further comprising at least one of:

selectively providing gaseous oxygen or air to said bioreactor; and

selectively providing carbon dioxide to said source.

63. Method according to any one of claims 39 to 62, wherein a portion of said media is fixed in situ within the bioreactor.

64. Method according to any one of claims 39 to 63, wherein at least a portion of said media is mobile within the bioreactor.

65. Method according to any one of claims 39 to 64, wherein said media comprise biofilm carrier elements, in the form of solid inert substrates having a relatively large surface area to volume ratio.

66. Method according to any one of claims 39 to 65, comprising:

partially or fully shielding the respective aerobic processing volume from light;

ensuring that the respective reservoir volume is exposed to light.

67. Method according to any one of claims 39 to 66, wherein step of aerobically reacting waste includes providing a through-flow of at least the oxygen-rich liquid medium through the bioreactor at a predetermined velocity, wherein said predetermined velocity is sufficient to cause the media therein to expand and to mix therein with at least the oxygen-rich liquid medium.

68. Method according to any one of claims 39 to 67, wherein said method is performed in batch mode.

69. Method according to any one of claims 39 to 67, wherein said method is performed in continuous flow mode.

70. Aerobic bioreactor configured for aerobically processing waste via bacteria fixed on media that are mobile within the aerobic bioreactor to provide processed effluent from the waste, comprising:

a reaction vessel having a fluid inlet and a fluid outlet, and a waste inlet, and defining an internal volume;

said waste inlet being configured for selectively providing waste to said aerobic bioreactor;

said fluid inlet and said fluid outlet being connectable to a source of oxygen-rich liquid medium, the source being different from said aerobic bioreactor, wherein said source is in selective fluid communication with said aerobic bioreactor via said fluid inlet and said fluid outlet to provide a recirculation circuit configured for controllably recirculating at least the liquid medium between said aerobic bioreactor and the source;

the reaction vessel being configured for providing, via said recirculation circuit, a through-flow of at least the oxygen-rich liquid medium through said internal volume at a predetermined velocity, wherein said predetermined velocity is sufficient to cause the media to expand within the reaction vessel and mix therein with at least the oxygen-rich liquid medium.

71. Aerobic bioreactor according to claim 70, wherein said predetermined velocity is sufficient to provide a fluidized bed effect to the media within said reaction vessel.

72. Aerobic bioreactor according to claim 70 or claim 71, wherein at said predetermined velocity is sufficient to provide upward motion to at least a first proportion of said media having a density greater than that of said liquid medium.

73. Aerobic bioreactor according to claim 72, wherein said flow velocity within said reaction vessel is in a direction generally opposed to the gravitational gradient.

74. Aerobic bioreactor according to claim 73, wherein said first proportion is a majority of the total amount of said media in said reaction vessel.

75. Aerobic bioreactor according to any one of claims 72 to 74, wherein said fluid inlet is provided at a lower part of the reaction vessel and said fluid outlet is provided at an upper part of the reaction vessel.

76. Aerobic bioreactor according to any one of claims 72 to 75, wherein said fluid inlet comprises a plurality of openings within said reaction vessel, and wherein said openings are distributed over a bottom base of the reaction vessel providing a desired coverage with respect to the bottom base.

77. Aerobic bioreactor according to claim 76, wherein said openings are uniformly distributed over a bottom base of the reaction vessel providing a full coverage with respect to the bottom base.

78. Aerobic bioreactor according to any one of claims 72 to 77, wherein said reaction vessel comprises one or more draft tubes, each draft tube being configured to further increase said fluid velocity therein.

79. Aerobic bioreactor according to claim 78, wherein each said draft tube provides an initially decreasing flow area in the direction of flow therethrough.

80. Aerobic bioreactor according to claim 78 or claim 79, wherein said openings of said fluid inlet are uniformly distributed over a part of bottom base of the reaction vessel opposite said draft tubes providing a full coverage with respect to the draft tubes.

81. Aerobic bioreactor according to claim 70 or claim 71, wherein at said predetermined velocity is sufficient to provide downward motion to said media having a density less than that of said liquid medium.

82. Aerobic bioreactor according to claim 81, wherein said flow velocity within said reaction vessel is in at least partially aligned with the gravitational gradient, and wherein at least a second proportion of said media has a density less than that of said liquid medium.

83. Aerobic bioreactor according to claim 82, wherein said second proportion is a majority of the total amount of said media in said reaction vessel.

84. Aerobic bioreactor according to any one of claims 81 to 83, wherein said fluid inlet is provided at an upper part of the reaction vessel.

85. Aerobic bioreactor according to any one of claims 81 to 84, wherein said reaction vessel comprises one or more draft tubes, each draft tube being configured to further increase said fluid velocity therein.

86. Aerobic bioreactor according to claim 85, wherein said openings of said fluid inlet are uniformly distributed over an upper opening of each said draft tubes providing a full coverage with respect to the draft tubes.

87. Aerobic bioreactor according to claim 86, wherein each said draft tube provides an initially decreasing flow area in the direction of flow therethrough.

88. Aerobic bioreactor according to any one of claims 70 to 87, further comprising a first sludge receiving receptacle at a lower part thereof for receiving and disposing of sludge from the aerobic bioreactor.

89. Aerobic bioreactor according to any one of claims 70 to 88, further comprising a clarifying vessel on an upper part of said reaction vessel and in fluid communication therewith, wherein said fluid outlet is provided on said clarifying vessel, and wherein said clarifying vessel is configured for reducing said fluid velocity therein.

90. Aerobic bioreactor according to claim 89, wherein said clarifying vessel comprises a cross-sectional area that increases in an upward direction.

91. Aerobic bioreactor according to claim 89 or claim 90, wherein said clarifying vessel comprises a second sludge receiving receptacle at a lower part thereof for receiving and disposing of sludge from the clarifying vessel.

92. Aerobic bioreactor according to any one of claims 70 to 91, further comprising an effluent outlet for removing processed effluent from said aerobic bioreactor.

93. A system for processing waste, comprising:

an aerobic bioreactor as defined in any one of claims 70 to 92;

the source of oxygen-rich liquid medium as defined in any one of claims 70 to 92, wherein said fluid inlet and said fluid outlet are connected to the source of oxygen-rich liquid medium; and

the media as defined in any one of claims 70 to 92, and provided in said aerobic bioreactor.

94. System according to claim 93, wherein said system is configured for preventing the media from being transferred from the aerobic bioreactor to said source.

95. System according to any one of claims 93 to 94, wherein said media is restricted to a confined volume within said aerobic bioreactor.

96. System according to any one of claims 93 to 95, wherein said source comprises photosynthetic microorganisms that generate oxygen to said liquid medium responsive to exposure to light.

97. System according to any one of claims 93 to 96, wherein said source comprises any one of photosynthetic eukaryotic microorganisms and photosynthetic prokaryotic microorganisms that generate oxygen to said liquid medium responsive to exposure to light.

98. System according to any one of claims 93 to 97, wherein said source comprises algae that generate oxygen to said liquid medium responsive to exposure to light.

99. System according to any one of claims 96 to 98, wherein said photosynthetic microorganisms comprise at least one of: Chlorella spp, spirulina, scendesmus, or any other photosynthetic microalgae or cyanobacteria.

100. System according to any one of claims 93 to 99, wherein said source comprises a reservoir comprising a channel therein defining a reservoir internal volume, and configured for driving said liquid medium around said channel in operation of the system.

101. System according to any one of claims 93 to 100, further comprising an auxiliary aeration system, configured for selectively providing gaseous oxygen or air to said bioreactor.

102. System according to any one of claims 93 to 101, further comprising an auxiliary CO₂system, configured for selectively providing carbon dioxide to said source.

103. System according to any one of claims 93 to 102, wherein a portion of said media is fixed in situ within the bioreactor.

104. System according to any one of claims 93 to 103, wherein said media comprise biofilm carrier elements, in the form of solid inert substrates having a relatively large surface area to volume ratio.

105. System according to any one of claims 93 to 104, comprising a waste inlet configured for receiving the waste and a dispensing outlet for dispensing treated effluent, and wherein:

said internal volume is partially or fully shielded from light at least during operation of the system;

106. System according to claim 105, wherein said driving device comprises a powered paddling device mounted to the respective said reservoir.

107. System according to claim 105 or claim 106, wherein said at least one reservoir comprises at least one flow channel in the form of a horizontal endless loop.

108. System according to claim 107, wherein said at least one flow channel has an annular plan form.

109. System according to any one of claims 105 to 108, wherein said source fluid medium outlet is configured for preventing outflow of said media therethrough.

110. System according to any one of claims 105 to 108, comprising:

111. System according to any one of claims 93 to 110, wherein said waste is aerobically treatable for removing pollutants therefrom.

112. System according to any one of claims 93 to 111, wherein said waste is a liquid waste.

113. System according to any one of claims 93 to 112, wherein said waste comprises at least one of waste water; organic types of waste; at least one of animal, agricultural, industrial or human waste transported in water or another liquid medium.