OA21078A - Systems and methods for algae cultivation using direct air capture. - Google Patents
Systems and methods for algae cultivation using direct air capture. Download PDFInfo
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- OA21078A OA21078A OA1202200527 OA21078A OA 21078 A OA21078 A OA 21078A OA 1202200527 OA1202200527 OA 1202200527 OA 21078 A OA21078 A OA 21078A
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Abstract
Embodiments of the disclosure provide systems and methods for supplying an algae cultivation fluid with nutrients (e.g., carbon dioxide and nitrogen) directly from the atmosphere. Supplying nutrients directly from the atmosphere reduces operational costs and environmental impacts, as well as provides greater flexibility in locating algae farms.
Description
SYSTEMS AND METHODS FOR ALGAE CULTIVATION USING DIRECT AIR CAPTURE
CROSS REFERENCE TO RELATED APPLICATIONS
[000l] This application claims priority to and the benefît of U.S. Patent Application No. 63/038,021, filed June 11,2020, the contents of which are herein incorporated by reference.
GOVERNMENT SUPPORT
[0002] This invention was made with government support under Grant No. DEEE0008639 and DE-EE0008516 awarded by the U.S. Department of Energy. The government has certain rights in the invention.
BACKGROUND
[0003] Algae utilises the suppiy of nutrients for cultivation. Algae utilize photosynthesis to fîx CO2 for growth. Typically, high intensity cultivation in an algae farm utilizes addition of CO2 in some form to support a high productivity. In some cases, pure CO2 is bubbled into the raceways to support high rates of photosynthesis. This approach enables locating algae farms almost anywhere, but the cost of buying the CO2 îs high, typically over $100 per ton in 2020 dollars. Utilizing a moderately concentrated CO2 source, e.g. 1% to 20% CO2 by volume, such as generated by combustion fine gas is less expensive than purchasing pure CO2 but limits the algae farm to being located near a source of CO?.
[0004] Algae utilize a nitrogen source for growth as well. Some blue-green algae or cyanobacteria can fix N2 dîrectiy from the atmosphère; however, the absorption rate of N2 becomes rate limiting during periods of high productivity. In column or fiat panel closed photobioreactors, a high rate of air bubbling is used to suppiy enough N2 absorption to support high productivity. Typical raceway cultivation does not hâve the intense air mixing that is present in these Systems, so high productivity is not attained with N2 absorption from the atmosphère as the nitrogen source for growth.
SUMMARY OF THE INVENTION
[0005] The present disclosure provides Systems and methods for suppiying an algae cultivation fluid with nutrients (e.g., carbon dioxide and nitrogen) directly from the atmosphère or air. Suppiy ing nutrients directly from the atmosphère reduces operational costs and environ mental impacts, as well as provides greater flexibility in locating algae farms.
[0006] The Systems and methods provided herein provide advantages over existing Systems including, but not limited to, încreased biomass productivity (g/m2d) of algae that can be supported with direct air capture of carbon dioxide for pli operating ranges of 9.0 or greater; încreased biomass productivity that can be supported with direct air capture of nitrogen allowing for higher carbon dioxide capture at lower pH values (e.g., at pH values lower than 10.2); încreased range of species that can be grown using direct air capture of carbon dioxide due to expanded pH ranges; reduced energy use required for direct air capture of nitrogen and carbon dioxide in algae cultivation fl nids; încreased response and recovery to process perturbations; and reduced impact of perturbations on the biomass productivity.
[0007] In some configurations, the present disclosure provides a method comprising the steps of culturing algae in at least one channel having a sloped bottom surface, a pair of opposing side walls, and an algae cultivation fluid disposed in the at least one channel. The method further includes applying bore waves through the algae cultivation fluid at a bore wave frequency sufficient to disrupt an air-liquid interface of the algae cultivation fluid to induce direct absorption of atmospherîc carbon dioxide or atmospheric nitrogen from air into the algae cultivation fluid, where a majority ofthe carbon or nitrogen in the algae is from the atmospheric carbon dioxide or atmospheric nitrogen.
[0008] in some embodiments, the bottom surface ofthe channel is sloped.
[0009] In some embodiments, the si ope of the bottom surface is less than 0.5%.
[0010] In some embodiments, the method includes passing the bore waves through one or more air-liquid mixing device configured within the at least one channel.
[00 11] In some embodiments, the at least one channel include from one air-liquid mixing device for every 300 ft2 of surface of the at least one channel to one air-liquid mixing device for every 400,000 ft2 of surface of the at least one channel.
[0012] In some embodiments, the one or more the air-liquid mixing devices are powered by the flow of the bore wave. In some embodiments, a rate of air-liquid mixing îs adjusted during the cultivation to reduce the energy consumption. In some embodiments, solar energy is used to power the at least one air-liquid mixing device, and wherein a rate of air-liquid mixing is greater during times of higher solar radiation relative to times of lower solar radiation,
[0013] In some embodiments, the air-liquid mixing device generates air bubbles in the algae cultivation fluid. The bubble génération rate may be încreased when the bore wave passes the air-liquid mixing device, and may be decreased during the period in between the bore waves.
[0014] In some embodiments, the at least one channel has a surface area of at least 100 ft2.
In some embodiments, the at least one channel has a surface area from 10,000 ft2 to 20,000,000 ft2. In some embodiments, the bore wave frequency, intensity, or a combination thereof is adjusted to obtain a minimum bicarbonate concentration in the algae cultivation fluid from l mM to 150 mM, or from 10 mM to i50 mM, or from 50 mM to ] 50 mM. In some embodiments, an équivalent bicarbonate concentration of sodium ions in the algae cultivation fluid is from 10 mM to 500 mM. [0015] In some embodiments, an équivalent bicarbonate concentration of sodium ions in the algae cultivation fluid and the bore wave frequency are selected to maîntain a différence between a maximum and minimum pH during day light hours of less than 0.8 pH units, or less than 0.7 pH units, or less than 0.5 pH units, or less than 0.4 pH units, or less than 0.3 pH units. [00I6] In some embodiments, the bore wave frequency, intensity, or a combination thereof is adjusted to maîntain a pH in the algae cultivation fluid of less than 11, or less than 10.6, or less than I0.2.
[0017] In some embodiments, the bore wave frequency is adjusted by displacing a gâte in a bore wave generator. In some embodiments, the gâte is displaced at a frequency from 10 seconds to 300 seconds to apply the bore waves through the algae cultivation fluid. in some embodiments, the bore wave intensity îs adjusted by the heîght of the algae cultivation fluid behind a gâte in a bore wave generator. In some embodiments, the height of the algae cultivation fluîd îs adjusted by the rate of fl U ing of an area behind the gâte with the algae cultivation fluid.
[0018] In some embodiments, the method includes measuring at least one process parameter in the algae cultivation fluid, and adjusting the bore wave frequency, intensity, or a combination thereof based on the at least one parameter or rate of change of the at least one parameter. In some embodiments, the parameter is selected from the group consisting of a pH, a dissolved oxygen content, a bicarbonate concentration, a nitrogen concentration, solar intensity, algae growth rate, turbidity, opiical density, and temperature. In some embodiments, the method includes adjusting the bore wave frequency, intensity or a combination thereof to ma intain a desired set-point of the at least one process parameter.
[00191 In some configurations, the present disclosure provides an algae cultivation system comprising at least one channel having a sloped bottom surface, a pair of opposing side walls, and an algae cultivation fluid disposed in the at least one channel. In some embodiments, the sloped bottom surface has a drop-offthat interrupts the sloped boitom surface. In some embodiments, the drop off has a height that is greater than a depth of the algae cultivation fluid în the at least one channel.
[0020] In some embodiments, the height of the drop off is from ] cm to 20 cm greater than the depth of the algae cultivation fluid in the at least one channel. In some embodiments, the siopped bottom surface has a slope percentage from 0% to I%. In some embodiments, the dropoff includes at least one weir. In some embodiments, the weir has a height that extends at least
50% of a depth of the algae cultivation fluid dîrectly above the drop-off.
[0021] In some configurations, the present disclosure provides an algae cultivation system. The algae cultivation system includes at least one channel having a sioped bottom surface, a pair of opposing side walls, and an algae cultivation fluid disposed in the at least one channel, the at least one channel having a cross-sectional area. The system further includes a narrowed région in the at least one channel, the narrowed région having a cross-sectional area that is smalier than the cross-sectional area of the at least one channel. In some embodiments, the system further includes a diffuser positioned in the narrowed région. The diffuser is coupled to a pipe that extends above an air-lîquid interface of the algae cultivation fluid to place the diffuser in fluid communication with air, the diffuser having a plurality of apertures that are configured to dispense the air into the algae cultivation fluid.
[0022] In some embodiments, the opposing side walls hâve a segment that protrudes inward within the at least one channel to form the narrowed région. In some embodiments, the sioped bottom surface includes a protrusion that extends vertically upwards to form the narrowed région. In some embodiments, the sioped bottom surface includes a drop-off that forms the narrowed région.
[0023] In some configurations, the present disclosure provides an algae cultivation system. The algae cultivation system includes at least one channel having a sioped bottom surface extending from a high end to a low end, a pair of opposing side walls, and an algae cultivation fluid disposed in the at least one channel. The system includes a sump connected to a low end of the sioped bottom surface, where the sump includes opposing sump walls connected to a sump bottom. The system includes a dividing wall the séparâtes the sump into a fluid collection side and an air-lift side. A diffuser is positioned on the air-lift side and in fluid communication with an air transfer device that dispenses air into the diffuser. The diffuser has a plurality of apertures that are configured to dispense the air into the algae cultivation fluid and transport the algae cultivation fluid from a bottom end of the sump to a holding section configured above the sump.
[0024] In some configurations, the present disclosure provides an algae harvesting system comprising a housing having a liquid inlet, a retentate outlet, a permeate outlet, a gas inlet, and a gas outlet. The housing comprises a membrane that séparâtes the housing into a permeate side and a retentate side. The algae harvesting system further includes an algae cultivation System in fluid communication with the liquid inlet, the algae cultivation system comprising algae cultivation fluid and algae, where the membrane séparâtes the algae cultivation fluid and algae into an algae paste that exits the housing through the retentate outlet and a permeate fluid that exits the housing through the permeate outlet. The algae harvesting System further includes a gas conduit that places the housing in fluid communication with a gas supply unit via the gas inlet, the gas supply unit configured to transport air into the gas inlet and enrich the permeate fluid with carbon dioxide or nitrogen to form a bicarbonate- or nitrogen-rich permeate fluid.
[0025] In some configurations, the present disclosure provides a method including the steps of feeding algae cultivation fluid and algae into a liquid inlet of an algae cultivation harvester, separating the algae cultivation fluid and the algae into an algae paste and a permeate stream by contacting the algae cultivation fluid and algae to a membrane in the algae cultivation harvester, and feeding air into the algae cultivation harvester to enrich the permeate stream with carbon dioxide or nitrogen to form a bicarbonate or nitrogen rich permeate stream.
[0026] In some configurations, the present disclosure provides a method including the steps of culturing a nitrogen fixing algae in ai least one channel having a bottom surface, opposing side walls coupled to the bottom surface, and an algae cultivation fluid disposed in the at least one channel, and applying bore waves through the algae cultivation fluid at a bore wave frequency sufficient to dîsrupt an air-liquid interface of the algae cultivation fluid to induce direct absorption of atmospheric nitrogen from air into the algae cultivation fluid, where a majorîty ofthe nitrogen in the algae is from the atmospheric nitrogen.
[0027] In some configurations, the present disclosure provides a method including culturing algae in at least one channel having a bottom surface, opposing side walls coupled to the bottom surface, and an algae cultivation fluid disposed in the at least one channel, and where the at least one channel contains at least one air-liquid mixing device that induces direct absorption of atmospheric nitrogen or carbon dioxide from air into the algae cultivation fluid, where the airliquid mixing device is operated such that the majority of the nitrogen or carbon in the algae is from the atmospheric nitrogen or atmospheric carbon dioxide.
[0028] These and other advantages and features of the invention will become more apparent from the following detailed description of the preferred embodiments of the invention when viewed in conjunction with the accompanying drawings.
DESCRIPTION OF THE DRAWINGS
[0029] FIG. i is an exemplary graph of vapor-liquid equiIibria between carbon dioxide and an algae cultivation fluid.
[0030] FIG. 2 is a schematic illustration of an algae cultivation system in accordance with some embodiments of the present disclosure.
[003] ] FIG. 3 is a cross-sectional view of a bore wave generator in accordance with some embodiments of the present disclosure.
[0032] FIG. 4 is an image of an exemplary bore wave in accordance with some embodiments of the present disclosure.
J
[0033] FIG. 5 is a schematic illustration of an air-liquîd mixing device in accordance with some embodiments of the present disclosure.
[0034] FIG. 6 is a schematic illustration of an air-liquid mixing device în accordance with some embodiments of the present disclosure.
[0035] FIG. 7 is a schematic illustration of an air-liquid mixing device in accordance with some embodiments of the present disclosure.
[0036] FIG. 8 is a schematic illustration of an air-liquid mixing device în accordance with some embodiments of the present disclosure.
[0037] FIG. 9 is a schematic illustration of an air-liquid mixing device in accordance with some embodiments ofthe present disclosure.
[0038] FIG. 10 is a schematic illustration of an air-liquid mixing device în accordance with some embodiments of the present disclosure.
[0039] FIG. 11 is a schematic illustration of an aigae cultivation system in accordance with some embodiments of the present disclosure.
[0040] FIG. 12 is a schematic illustration of an air-liquid mixing device and bore wave generator in accordance with some embodiments of the present disclosure.
[0041] FIG. I3 is schematic illustration ofan example harvester in accordance with some embodiments ofthe present disclosure.
[0042] FIG. 14 îs a schematic illustration of a process control System in accordance with some embodiments of the present disclosure.
[0043] FIG. 15 is a flow chart illustrating exemplary steps of a method in accordance with some embodiments of the present disclosure.
[0044] FIG. 16 îs a graph of biomass productivity in accordance with some embodiments of the present disclosure.
DETAILED DESCRIPTION
[0045] As noted above, high levels of aigae biomass productivity (g/m2d) utilize supplémentation of gaseous nutrients, such as carbon dioxide and nitrogen, for cultivation. Typically, cultivation farins utilize the addition of concentrated carbon dioxide or flue gas as a source for carbon dioxide. These approaches increase operating costs of the cultivation farm, and in the case of flue gas utilization, can limit the location of the farm.
[0046] The present disclosure addresses the aforementioned drawbacks by providing
Systems and methods for supplying an aigae cultivation fluid 12 with nutrients (e.g., carbon dioxide and nitrogen) directly from air (e.g., gases within the atmosphère). In some embodiments, the present disclosure provîdes Systems and methods that may maintain a sufficient concentration of
J carbon dioxide and nitrogen in an algae cultivation fluid 12 for biomass productivîty of at least 8 g/m2d using direct capture of atmospheric carbon dioxide and atmospheric nitrogen. In some embodiments, the Systems and methods provided herein are performed without applying, supplementing, or treating an algae cultivation fluid 12 with concentrated carbon dioxide, concentrated nitrogen, and/or flue gas.
[0047] As used herein, the terms air and atmosphère may refer to gases surroundîng the earth, which may vary regionally, and are a function of various factors, such as température and pressure. As one example, the terms air and atmosphère may refer to a gaseous composition composed, in a dry volume percentage (vol %), of about 78 vol% nitrogen, about 20.9 vol% oxygen, about 0.9 vol% argon, about 0.04 vol% carbon dioxide, and other éléments and compounds such as hélium, methane, krypton, hydrogen, nitrous oxide, xénon, ozone, carbon monoxide, sulfur dioxide, nitrogen dioxide, and ammonia. As used herein, the term atmospheric carbon dioxide may refer to carbon dioxide derived from air, and the term atmospheric nitrogen refers to nitrogen derived from air.
[0048] As used herein, the terms concentrated carbon dioxide and concentrated nitrogen refer to a carbon dioxide or nitrogen source containing between 20 vol% to 100 vol% carbon dioxide or nitrogen, based on the total volume ofthe source. Example concentrated carbon dioxide or nitrogen sources included pressurized vessels containing the specifîed volume percentage of carbon dioxide or nitrogen. As used herein, the term flue gas refers to exhaust gas exiting a pipe or channel from a Chemical process or plant (e.g., furnace, boiler, steam generator), which is composed of from l vol% to 20 vol% carbon dioxide and at least 65 vol% nitrogen.
i. Carbon Dioxîde-Algae Cultivation Fluid Equilibria:
[0049] FIG. I illustrâtes the pH at which the partial pressure of carbon dioxide from algae cultivation fluid I2 is in equilibrium with the partial pressure of air as a function of the équivalent bicarbonate concentration. As used herein, the term équivalent bicarbonate or équivalent bicarbonate concentration may refer to the molarity of sodium ions that are paired with bicarbonate and/or carbonate ions to provide a concentration of carbon dioxide dissolved in the algae cultivation fluid 12. As shown in FIG. I, if the media pH is higher than the equilibrium curve at the équivalent bicarbonate loading in the algae cultivation fluid 12, then there is a driving force for carbon dioxide capture from the air, and the algae cultivation fluid 12 will absorb atmospheric carbon dioxide.
[0050] Operating under high pH allows for the spontaneous absorption of carbon dioxide into the algae cultivation fluid 12. Although this is an effective technique for stnall scale cultivation farms (e.g., less than 2 square feet), as the size of the cultivation farm increases to larger scales (e.g., greater than 10 square feet), lhe spontaneous diffusion of carbon dioxide is diffusion limited, and becomes insufficient for providing algae with proper levels of carbon dioxide and nitrogen for large scale production. That is, the spontaneous diffusion of carbon dioxide into the cultivation media, along with standard paddle wheel circulation, for cultivation farms larger than 10 square feet is insufficient to maintain an average équivalent bicarbonate level that îs suitable for biomass productivité' of greater than 8 g/m2d of algae, unless the pH is very high, e.g., greater than 10.8, such that there are few algae that can grow at this productivité.
[0051] The present disclosure provides Systems and methods for improving direct air capture of atmospheric carbon dioxide and atmospheric nitrogen into algae cultivation fluid 12. In some embodiments, the algae cultivation Systems provided herein allow for sufficient direct absorption of atmospheric carbon dioxide to maintain an average équivalent bicarbonate concentration of at least l mM in the algae cultivation fluid 12, hâve a biomass productivity of at least 8 g/m2d, and maintain these specified parameters while operating within a raceway and/or channel size of at least 10 square feet.
II. Algae Cultivation System:
[0052] The present disclosure provides an algae cultivation system l. FIG. 2 illustrâtes an algae cultivation system l in accordance with some embodiments of the present disclosure. The algae cultivation system l includes a first channel 2. The channel bottom may be fiat or sloped. In some embodiments, the first channel 2 includes a sloped bottom 6a and opposing side walls 5a, 5b coupled to the sloped bottom 6a. A pump system 8a, 8b moves an algae cultivation fluid 12 from the first channel 2 to a second channel 3. The second channel 3 includes a sloped bottom 6b and opposing sidewalls 5b, 5c coupled to the sloped bottom 6b. As illustrated in FIG. 2, the channels 2, 3 may share a central sidewall 5b. Although not illustrated in FIG. 2, each channel 2, 3 may be separated by a spacing where each channel 2, 3 has its own opposing sidewalls.
[0053] In some embodiments, the pump 8a moves the algae cultivation fluid 12 within channel 2 along a flow path vl that extends from a high end 10a to a low end 10b ofthe sloped bottom 6a. The pump 8b may receive the algae cultivation fluid 12 at the low end 10b, and move the algae cultivation fluid 12 from the low end 10b of sloped bottom 6a in the first channel 2 to a high end 9a of sloped bottom 6b in the second channel 3.
[0054] In some embodiments, the pump 8b moves the algae cultivation fluid 12 within channel 3 along a flow path v2 that extends from the high end 9a to a low end 9b of the sloped bottom 6a. In some embodiments, the pump 8a moves the algae cultivation fluid 12 from the low end 9b of sloped bottom 6b in the second channel 3 to a high end !0a of sloped bottom 6a în the first channel 2. In this way, the pump system 8a, 8b circulatethe algae cultivation fluid 12 through the algae cultivation system l.
[0055] Although FIG. 2 illustrâtes a two channel system, it is to be appreciated that a sériés of interconnected channels may be used. For example, rather than using pump 8a to recirculate the algae cultivation fluid 12 flowing from the second channel 3 to the first channel 2, a third pump (not shown) could move the algae cultivation fluid 12 from the low end 9b of the sloped bottom 6b to a high end of a sloped bottom in a third channel (not shown). This process may be repeated using a sériés of channels having the same or similar structure to channels 2, 3. In some embodiments, the algae cultivation system l includes at least 2 channels, or at least 3 channels, or at least 4 channels, or at least 5 channels, to fewer than 10 channels, or fewer than 20 channels, or fewer than 30 channels, or more. In some embodiments, a last channel in the sériés of channels may include a recirculation loop that îs connected to the high end 10a of the first channel 2, estabiishing a continuons flow loop for the algae cultivation fluid 12 within the algae cultivation system l. Additionally, it is to be appreciated that a single channel system may be used. For example, the pump system 8a, 8b may circulate the algae cultivation fluid 12 in a continuons loop within a single channel, which may be sloped or fiat.
[0056] In some embodiments, the channels 2, 3 hâve a cross-sectional shape that includes, but is not limited to, a square, a rectangular, or a trapézoïdal shape. In some embodiments, the channels 2, 3 hâve a square or rectangular cross-sectional shape where the opposing sidewalls 5a, 5b, 5c are perpendicular to the sloped bottom 6a. In sortie embodiments, the opposing sidewalls 5a, 5b, 5c may be slanted at an angle creating a trapézoïdal cross-sectional shape.
[0057] In some embodiments, the channels 2, 3 are earthen channels. As used herein, the tenu earthen channel may refer to an elongate void in the earth where the sidewalls 5a, 5b, 5c and the sloped bottoms 6a, 6b are composed of earthen materials, such as soil. The earthen channel may be lined with a liner. Suitable liners include, but are not limited to, plastic liners and building materials, such as concrète, cernent, mortar, brick, and combinations thereof.
[0058] In some embodiments, the algae cultivation System l includes a bore wave generator 11 positioned în the one or more channel 2, 3. The bore wave generator 11 may be positioned downstream ofthe pumps 8a, 8b.
[0059] Referring to FIG. 3, the bore wave generator 11 may include a moveable gâte 13 that impedes or prevents the flow of algae cultivation fluid 12 within the channels 2, 3. When in a closed position, the moveable gâte 13 accumulâtes algae cultivation fluid 12 on the pump side of the gâte 13. The gâte 13 may periodically displace (e.g., lift) to release a bore wave of algae cultivation fluid 12 that flows down the channels 2, 3.
[0060] In some embodiments, the gâte 13 is displaced at a frequency from 10 to 300 seconds, which may be used to control a bore wave frequency within the channels 2, 3. In some embodiments, the gâte 13 îs displaced manually, or controlled by a controller, at a frequency of at least 10 seconds, or at least 15 seconds, or at least 30 seconds, or at least 45 seconds, or at least every 60 seconds, to fewer than 90 seconds, or fewer than 120 seconds, or fewer than 150 seconds, or fewer than 180 seconds, or fewer than 240 seconds, or fewer than 300 seconds. The bore wave frequency is increased proportionally to the flow pumps 8a, 8b, i.e. a higher flow rate is required for higher frequency and a lower flow rate for lower frequency.
[0061] In some embodiments, the flow generated by pumps 8a, 8b is increased while the displaced frequency for gâte 13 is held constant to increase the intensity of the bore wave by încreasing the height and volume of fluid behind the gâte prior to displacing the gâte. The flow generated by pumps 8a, 8b can also be decreased to lower the intensity of the bore wave. In some embodiments, the gâte 13 is displaced when the height ofthe fluid behind the gâte compared to the height of the fluid downstream of the gâte îs at least 2 cm or at least 4 cm or at least 6 cm or at least 10 cm or at least 20 cm or at least 30 cm to less than 60 cm or less than 90 cm or less than 120 cm. The height of fluid may be monitored or determined using a sensor (e.g., level sensor).
[0062] Bore waves create intense mixing between air and the algae cultivation fluid 12, as illustrated in Fig. 4, The wave front 14 is constantly breaking, which créâtes additional surface area from the splashing and the height of the wave front 14. Further, the wave front 14 entraps air that is driven down into the algae cultivation fluid 12. As the wave front 14 passes, these air bubbles are mixed in the high turbulence that follows the wave 15 before eventually rising to the surface. This générâtes a large amount of additional gas-liquid interface area together wîth high mixing rates that reduces the boundary layer and increases carbon dioxide and nitrogen absorption rate per area. The bore wave frequency or intensity can be varied, so that higher surface area and mixing are generated, e.g. încreasing the wave frequency or intensity to provide more carbon dioxide during the high productivity times, and lower energy is used during lower productivity periods, e.g. reducing the wave frequency or intensity.
[0063] Referring back to FIG. 2, in some embodiments, the algae cultivation system 1 includes at least one air-liquid mixing device 7. The at least one air-liquid mixing device 7 is configured to disrupt an air-liquid interface on the algae cultivation fluid 12 to enhance the absorption rate of atmospheric carbon dioxide and atmospheric nitrogen.
[0064] In some embodiments, the channels 2, 3 includes from 2 to 30 air-liquid mixing devices. In some embodiments, the channels 2, 3 includes at least 2 air-liquid mixing devîces, or at least 3, or at least 4, or at least 5, to fewer than 10, or fewer than 15, or fewer than 20, or fewer than 25, or fewer than 30. In some embodiments, the channels 2, 3 includes from 1 to 30 bore wave generators U. In some embodiments, the channels 2,3 includes at least l bore wave generators 11, or at least 2, or at least 3, or at least 5, to less than 10, or less than 15, or less than 20, or less than 25, or less than 30.
[0065] In some embodiments, the air-Iiquid mixing device 7 may be powered by the flow of algae cultivation fluid 12. As used herein, the phrase powered by the flow of algae cultivation fluid may refer to passing the algae cultivation fluid 12 through and/or around the air-Iiquid mixing device 7 at a velocity sufficient to disrupt an air-Iiquid interface of the algae cultivation fluid to induce direct absorption of atmospheric carbon dioxide or atmospheric nitrogen into the algae cultivation fluid 12. In some embodiments, the phrase powered by the flow of algae cultivation fluid may refer to circulating the algae cultivation fluid 12 within the at least one channel 2, 3 at a velocity that is sufficient to move the air-Iiquid mixing device 7 to cause the airIiquid mixing device to disrupt an air-liquid interface of the algae cultivation fluid to induce direct absorption of atmospheric carbon dioxide or atmospheric nitrogen into the algae cultivation fluid 12.
[0066] FIG. 5 illustrâtes a cross-sectional view of an exemplary air-liquid mixing device 7 positioned in channel 2 of FIG. 2. In some embodiments, the air-liquid mixing device 7 includes a drop-off ! 7 (e.g., higher sloped région or vertical drop off région) in the sloped bottom 6a. The drop-off 1 7 generates a high mixing rate that enhances the gas-1 iquid interface area, and increases the carbon dioxide and/or nitrogen absorption rate into the algae cultivation fluid 12.
[0067] In some embodiments, a height 18 of the drop-off 17 is greater than a depth 19of the algae cultivation fluid 12 within the channel 2. In some embodiments, the depth 19 ofthe algae cultivation fluid 12 is defined by a distance between an air-liquid interface ofthe algae cultivation media to the sloped bottom 6a.
[0068] In some embodiments the height 18 ofthe drop-off 17 is at least 1.1 times greater than the depth 19 of the algae cultivation fluid 12, or at least 1.2 times greater, or at least 1.3 times greater, or at least 1.4 times greater, or at least 1.5 times greater, or at least 1.6 times greater, or at least 1.7 times greater, or at least 1.8 times greater, or at least 1.9 times greater, to less than 2 times greater, or less than 2.5 times greater, or less than 3 tîmes greater, or less than 3.5 times greater, or less than 4 times greater, or less than 5 times greater, or less than 6 times greater, or less than 7 times greater, or less than 8 times greater, or less than 9 times greater, or to less than 10 times greater.
[0069] In some embodiments, the height 18 of the drop-off 17 is at least 1 centimeter (cm) greater than the depth 19 of the algae cultivation fluid 12. In some embodiments, the height I8of the drop-off 17 is at least 1 cm greater than the depth 19, or at least 2 cm, or at least 3 cm, or at least 4 cm, or at least 5 cm, or at least 6 cm, or at least 7 cm, or at least 8 cm, or at least 9 cm, or
1 at least 10 cm, or at least 11 cm, or at least 12 cm, or at least 13 cm, or at least I4 cm, or at least 15 cm, to less than 20 cm, or less than 25 cm, or less than 30 cm, or less than 40, or less than 50, or less than 100 cm.
[0070] In some embodiments, the depth 19 ofthe algae cultivation fluid 12 is at least l cm, or at least 2 cm, or at least 3 cm, or at least 4 cm, or at least 5 cm, or at least 6 cm, or at least 7 cm, or at least 8 cm, or at least 9 cm, or at least 10 cm, to less than 15 cm, or less than 20 cm, or less than 30 cm, or less than 40 cm, or less than 50 cm.
[0071 ] In some embodiments, the drop-off 17 has a slope percentage that is greater than a slope percentage of the sloped bottom 6a. In some embodiments, the sloped bottom 6a continues after the drop-off 17 with the same or different slope percentage than the sloped bottom 6a upstream of the drop-off 17.
[0072] In some embodiments, the sloped bottoms 6a, 6b hâve a slope percentage of at least 0.1%. In some embodiments, the sloped bottoms 6a, 6b hâve a slope percentage of at least 0.01 %, or at least 0.02%, or at least 0.03%, or at least 0.04%, or at least 0.05%, to less than 0.06%, or less than 0.07%, or less than 0.08%, or less than 0.09%, or less than .1%, or less than 0.5%, or less than ]%, or less than 2%, or to less than 3%. As used herein, the term slope percentage may refer to the slope of the sloped bottoms 6a, 6b expressed as a percentage, e.g., (rise length/run length)xl00.
[0073] In some embodiments, the drop-off 17 has a steep slope percentage of at least 100%, or at least 200%, or at least 300%, or at least 400%, or at least 500%, or at least 600%, to less than 700%, or less than 800%, or less than 900%, or less than 1000%, or to a vertical dropoff.
[0074] As shown in FIG. 6, the drop-off 17 may include one or more weir 20. As used herein, the term weir may refer to a barrier across at least a portion of the width of the channel that alters the flow characteristics of the algae cultivation fluid 12. Passing the algae cultivation fluid 12 over the weirs créâtes turbulence and high air-lîquid mixing rates, thereby enhancing the absorption rate of carbon dioxide and/or nitrogen into the algae cultivation fluîd 12.
[0075] In some embodiments, a height 21 of the weir 20 is less than the depth of the algae cultivation fluid 12 so that the fluid flows over the top of the weir 20. In some embodiments, the height 21 of the weir 20 extends at least 50% of a depth ofthe algae cultivation fluid 12 above the drop-off 17, or at least 55%, or at least 60%, or at least 65%, or at least 70%, or at least 75%, to less than 80%, or less than 85%, or less than 90%, or less than 95% of the depth.
[0076] In some embodiments, the one or more weir 20 extends at least 10% the width of the channels 2, 3. In some embodiments, the one or more weir 20 extends at least 10% the width of the channels 2, 3, or at least 20%, or at least 30%, or at least 40%, or at least 50%, or at least
60%, or at least 70%, to less than 80%, or less than 90%, or the less than 95%, or to the entire width of the channels 2, 3.
[0077] In some embodiments, the drop-off 17 includes a sériés of weirs 20 along the length of the drop-off 17. In some embodiments, the drop-off 17 includes from l to 50 weirs 20. In some embodiments, the drop-off I 7 includes at least 2 weirs, or at least 3 weirs, or at least 4 weirs, or at least 5 weirs, or at least 6 weirs, or at least 7 weirs, or at least 8 weirs, or at least 9 weirs, to fewer than I0 weirs, fewer than 20 weirs, fewer than 30 weirs, fewer than 40 weirs, or fewer than 50 weirs.
[0078] In some embodiments, the drop-off 17 has a low slope percentage of at least 0.3%, or at least 0.4%, or at least 0.5%, or at least 0.6%, or at least 0.7%, or at least 0.8%, or at least 0.9%, or at least I %, or at least l .5%, or at least 2%, or at least 2.5%, or at least 3%, or at least 3.5%, or al least 4%, or at least 4.5%, to less than 5%, or less than 6%, or less than 7%, or less than 8%, or less than 9%, or less than 10%.
[0079] In some embodiments, the one or more weîr 20 includes a passage 22 that allows algae cultivation fluid 12 to drain. The passage 22 may allow the algae cultivation fluid i 2 to flow through or around the one or more weir 20. In some embodiments, the passage 22 îs a hole located in the bottom of the one or more weir 20. The passage 22 may be sized such that algae cultivation fluid 12 can drain from the drop-off 17 when recirculation ceases, but is smail enough such that a majority of the algae cultivation fluid flows over the one or more weir 20 during operation. In some embodiments, the weir 20 may hâve a notch in the plate that has a géométrie shape. The notch in the weir 20 may hâve a triangular (v-shaped), rectangular, trapézoïdal, or a compound shape (having at least two notch shapes in the weir).
[0080] FIGS. 7 illustrate a top and side view of an exemplary air-liquîd mixing device 7 positioned in channel 2 of FIG. 2. The air-liquid mixing device 7 includes a narrowed région 23 having a reduced cross-sectional area relative to the channel 2. In some embodiments, the narrowed région 23 is formed from the opposing sidewalls 5a, 5b protruding inward to form a reduced cross-sectional area with increased fluid velocity. The narrowed région 23 includes a diffuser 24 and one or more pipe 25 that rîses above the surface of the algae cultivation fluid 12 to place the diffuser 24 in fluid communication with the atmosphère.
[008l] The increased fluid velocity within the narrowed région 23 utilizes the Bernoulli effect to pull air from the atmosphère to the diffuser 24. The diffuser 24 includes a sériés of apertures that dispense the air into the algae cultivation fluid 12 (e.g., as bubbles). The bubbles hâve a high surface area and increase the absorption of carbon dioxide and/or nitrogen into the algae cultivation fluid 12.
I3
[0082] In some embodiments, the sidewalls 5a, 5b within the narrowed région 23 may hâve a géométrie shape. In some embodiments, the géométrie shape of the sidewalls 5a, 5b in the narrowed région 23 include, but is not limited to, an arcuate shape, a slanted shape, a square or rectangular shape. Alternatively or additîonally, the narrowed région 23 may be formed by adding a building materiai to the channel 2, such as soil, concrète, mortar, cernent, and combinations thereof, to reduce the cross section of the channel 2.
[0083] In some embodiments, the narrowed région 23 has a width 26. In some embodiments, the width 26 of the narrowed région 23 is less than 95% of a width 25 of the channel 2, or less than 90%, or less than 85%, or less than 80%, or less than 70%, or less than 60%, or less than 50%. or less than 40%, to at least 30%, or at least 20%, or at least 10% of the width 27 of the channel 2.
[0084] Fig. 8 provides a side view of an exemplary air-liquid mixing device 7 which includes an aîr transfer device 37 (e.g., blower or compresser) that is coupled to a diffuser 24 to generate bubbles in the algae cultivation fluid 12. The bubbles can be generated in a higher velocity zone or a zone with static mixers to provide additional turbulence to reduce the boundary layers and provide greater CO: and/or N2 absorption rate per gas-liquid area generated. Also, the size of the bubbles created can be controlied to provide enough résidence time in the media for absorption of CO2 and/or N2 from the air bubble. The size of the bubbles can be optimized based on pH. molarity, and cost of generating the bubbles versus CO2 capture efficiency to minimize the effective cost of CO2 supplîed from the air. The blower or compression devices can be powered by the flow of media including the flow of a bore wave. Advantages of using the flow of the media and/or flow of bore waves to power a device is that the expense of installing and maintaining power wiring is avoîded, and for bore waves, mixing can be varied based on the frequency and/or intensity of the waves.
[0085] In some embodiments, the bubbles can be generated by the air transfer device at a higher rate when each bore wave passes by so the bubbles will be entrained longer with more vigorous local mixing to increase the max transferefficiency. Timingthe release of bubbles in this way results in more efficient use of the energy used to generate bubbles because they are added when the efficiency of CO2 and/or N2 transfer is highest.
[0086] In some embodiments, the diffuser 24 extends along at least a portion or the entire width 26 of the narrowed région 23. In some embodiments, a sériés of pipes 25 are used to provide air to the diffuser. In some embodiments, from two to ten pipes 25 are used. In some embodiments, the one or more pipes 25 are positioned proximate or in contact with the sidew'alls 5a, 5b of the narrowed région 23.
[0087] FIG. 9 illustrâtes a side view of an exemplary air-liquid mixing device 7 positioned in channel 2 of FIG. 2. The air-liquid mixing device 7 includes a narrowed région 123 having a reduced cross-sectional area relative to the channel 2. in some embodiments, the narrowed région 123 is formed from the sloped bottom 6a generating a protrusion 126 that extends verticaily upwards to reduce the depth 19 of the algae cultivation fluid in the narrowed région 123 to form a reduced cross-sectional area with increased fluid velocity.
[0088] The narrowed région 123 includes a diffuser 124 and one or more pipe 125 that rises above the surface of the algae cultivation fluid 12 to place the diffuser 124 in fluid communication with the atmosphère. The diffuser 124 includes a sériés of apertures that dispense the air into the algae cultivation fluid I2. The diffuser I24 is placed in the narrowed région 123 where the increased fluid velocity produces a low enough pressure via the Bernoulli effect to pull air into the algae cultivation fluid 12 through the one or more pipes 125 and the diffuser 124.
[0089] In some embodiments, the protrusion I26 in the sloped bottom 6a has a géométrie shape. In some embodiments, the géométrie shape of the protrusion 26 in the narrowed région 23 includes, but is not limited to, arcuate walls forming a hemîspherical shape, a slanted shape forming a triangular or trapézoïdal shape, or vertical walls formîng a square or rectangular shape. [0090] In some embodiments, the protrusion 126 has a height 127 that is at least 5% of the depth 19 of the algae cultivation fluid (e.g., measured as the distance from the air-liquid interface to the sloped bottom 6a), or at least 10%, or at least J 5%, or at least 20%, or at least 25%, or at least 30%, or at least 35%, or at least 40%, or at least 45%, to less than 50%, or less than 55%, or less than 60%. or less than 65%, or less than 70%, or less than 75%, or less than 80%, or less than 85%, or less than 90%, or less than 95% of the depth 19.
[00911 In some embodiments, the diffuser 124 extends along at least a portion or the entire width of the narrowed région 123. In some embodiments, a sériés of pipes 125 are used to provide air to the diffuser 124. In some embodiments, from 2 to 10 pipes 25 are used. In some embodiments, the one or more pipes 125 are positioned proximale or in contact with the sidewalls 5a, 5b of the narrowed région 123.
[0092] FIG. 10 illustrâtes a side view of an example air-liquid mixing device 7 positioned in channel 2 of FIG. 2. As shown in FIG. 10, the diffuser 224 and one or more pipe 225 may be configured on a drop-off 17, which may produce a narrowed région 223 having a reduced cross sectional area. In some embodiments, the diffuser 224 extends along at least a portion or the entire length of the drop-off 17. In some embodiments, the diffuser 224 extends along at least 10% of the length of the drop-off 17, or at least 20%, or at least 30%, or at least 40%, or at least 50%, or at least 60%, or at least 70%, or at least 80%, or at least 90%, or 100% of the length of the dropoff 17.
[0093] FIG. H illustrâtes an aigae cultivation system l in accordance with some embodiments of the present disclosure. The aigae cultivation system l includes a channel 28 having sloped bottoms 6(c-h), an outer sidewall 5d, and an inner sidewall 5e coupled to the sloped bottoms 6(c-h). In some embodiments, the outer sidewall 5d forms an ellîptical shape and the inner side wall 5e is disposed within the outer sidewall 5d (e.g., centrally disposed) to form a continuously looping channel 28.
[0094] In some embodiments, the aigae cultivation System ] includes from 2 to 30 airliquid mixing devices 7 positioned within the channels 2, 3. In some embodiments, the channel 28 includes at least 2 air-liquid mixing devices 7, or at least 3, or at least 4, or at least 5, to less than 10, or less than 15, or less than 20, or less than 25, or less than 30.
[0095] In some embodiments, the aigae cultivation system l includes one or more bore wave generator 11 and one or more air-liquid mixing device 7 disposed within the channel 28. In some embodiments, the aigae cultivation system l includes a sériés of sloped bottoms 6(c-h), each of which extends from a high end to a low end. In some embodiments, the wave generators 11 and the air-liquid mixing devices 7 segment the channel 28 into the sloped bottom 6(c-h) régions.
[0096] FIG. 12 illustrâtes an exemplary air-liquid mixing device 7 and bore wave generator l l positioned in channel 28 of FIG. I l. In some embodiments, the sloped bottom 6c has a low end connected to a sump 29. The sump 29 includes oppostng sump walls 30, 31 that are connected to a sump bottom 32, which may be a sloped, curved or fiat. The sump 29 may include a dividing wall 33 that séparâtes the sump 29 into a fluid collection side 34 and an air-lift side 35. In some embodiments, the air-lift side 35 includes the air-liquid mixing device 7 that transfers the aigae cultivation fluid 12 from the sump 29 to a holding section 36.
[0097] In some embodiments, the air-liquid mixing device 7 includes an air transfer device 37 (e.g., blower or compressor) that is coupled to a diffuser 324 positioned on the air-lift side 35. The air transfer device 37 and diffuser 324 generate bubbles în the aigae cultivation fluid 12. The bubbles lower the average density on one side of the sump 29 causing the culture media 2 to flow up that side and into the holding section 36. The flow is increased or decreased by increasing or decreasing the flow of air to the diffuser 324. The fluid within the holding section 36 is regulated using a gâte 13 of a bore wave generator 11 and the rate of air flow to the diffuser 324. The gâte 13 displaces at a frequency to release and generate bore waves in the channel 28. At higher frequency and the constant intensity, a greater flowrate of air to the diffuser 324 is required, and at lower frequency and constant intensity, a lower flowrate of air to the diffuser 324 is required.
[0098] In some embodiments, the channel 28 includes a pump system 8 to facilitate the flow of aigae cultivation fluid 12 in the channel 28.
[0099] In some embodiments, the channel 28 includes from 2 to 30 air-liquid mixing devices 7. In some embodiments, the channel 28 includes at least 2 air-liquid mixing devices 7, or at least 3, or at least 4, or at least 5, to fewer than 10, or fewer than 15, or fewer than 20, or fewer than 25, or fewer than 30. In some embodiments, the channel 28 includes from 2 to 30 bore wave generators 11. In some embodiments, the channel 28 includes at least 2 bore wave generators 11, or at least 3, or at least 4, or at least 5, to less than 10, or less than 15, or less than 20, or less than 25, or less than 30.
[00100] In some embodiments, the channel 28 includes at least one air-liquid mixing device 7 per 300 ft2 surface area ofthe channel 28 to one air-liquid mixing device 7 per 400,000 ft2 surface area ofthe channel 28. In some embodiments, the channel 28 includes at least one air-liquid mixing device 7 per 400 ft2 surface area of the channel 28, or at least 500 ft2, or at least 1000 ft2, or at least 1500 ft2, or at least 2000 ft2, or at least 2500 ft2, or at least 3000 ft2, or at least 3500 ft2, or at least 4000 ft2, or at least 4500 ft2, or at least 5000 ft2, or at least 10,000 ft2, or at least 20,000 ft2, or at least 30,000 ft2, or at least 40,000 ft2, or at least 50,0000 ft2, to less than 100,000 ft2, or less than 200,000 ft2, or less than 300,000 ft2, or less than 400,000 ft2.
[00101] In some embodiments, the one or more air-liquid mixing device 7 in FIG. 2 or FIG. 1 1 may include fixed or rotating surfaces that break, chop or blend the surface to create splashing or bubble entrainment together with turbulent mixing. Examples of such rotating devices include disk aerators such as described in US patents 4,372,895 or 9,073,016; brush aerators such as described in US patents 3,561,738 or 2,684,941; paddlewheels such as described in US patents 6,994,329 or 5,116,501; and surface aerators such as described in US patents 6,715,912 or 6,877,959. Fixed or rotating surfaces can be combined with bore waves, cascades and/or waterfalls, for example, a waterfall could hit splash plates prior to falling into the culture media. The rotating devices could be powered by the flow of media including the flow of a bore wave. Advantages of using the flow of the media and/or flow of bore waves to power a device is that the expense of installing and maintaining power wiring is avoided, and for bore waves, mixing can be varied based on the frequency of the waves.
[00102] For devices that utilize external power such as rotating surfaces, blowers, compressors, or pumps for venturis, the rate of air-liquid surface area génération and mixing can be varied so that higher surface area and mixing are generated when it is needed to provide more CO? and/or Nz during the high productîvity times, and lower energy is used during lower productivity periods when it is not needed as described above for bore wave frequency. Additionally, the devices can utilize solar power to eliminate the expense of installing and maintaining power wiring throughout a multi-acre algae farm. The solar power can also be directiy utilized to provide variable mixing and minimize or elîminate the battery storage requirements as described above for dîrectly powering the wave generator.
[00103] Fig. 13 illustrâtes a system 38 for absorbing CO? from the air during harvest to provide another source of CO? that can be used for control during cultivation to improve stability and productivity in addition to the variable mixing described above. High productivity algae cultivation in large raceways with CO? supplied by direct air capture is supplemented through harvesting the algae and culture media at a high enough pH to provide a driving force for CO2 capture from the atmosphère and a high enough carbonate concentration to store CO2 in the media, separating the algae from the media in a harvest system that utiîizes air bubbles to assist în the harvesting, absorbing CO2 from the air into the media during the harvesting, and controlling return ofthe media containing the absorbed CO2 to the cultivation system. The timing ofthe media return to the cultivation system can be controlled based on the weather and productivity to provide extra CO? when it is needed for pH control or to support growth.
[00104] As shown în FIG. 13, algae and algae cultivation fluid 12 are transported from the algae cultivation system l to a harvester, which may be done via a pump. In some embodiments, the harvester includes a housing having a liquid inlet, a retentate outlet, a permeate outlet, a gas inlet, and a gas outlet. The housing may include a membrane that séparâtes the housing into a permeate side and a retentate side. The membrane séparâtes the algae cultivation fluid 12 into an algae paste that exits the housing through the retentate outlet and a permeate fluid that exits the housing through the permeate outlet. The permeate containing purified algae cultivation fluid may be recycled back to the algae cultivation system l.
[00105] In some embodiments, air is supplied to the harvester (e.g., in the form of bubbles) via a gas conduit during séparation. The harvester may hâve a gas outlet to dispense the air having reduced carbon dioxide and/or nitrogen concentration. The permeate containing purified algae cultivation fluid 12 may be enriched în carbon dioxide and/or nitrogen as it is recycled back to the algae cultivation system l.
[00 i 06] The optimum pH and équivalent bicarbonate molarity for use in the algae cultivation system l is dépendent on the species, the productivity, and contamination control. High pH and higher équivalent bicarbonate molarity can be used to limit the number of species that can contaminate a raceway. Higher équivalent bicarbonate molarity adds buffering capacity to reduce fluctuation in pH and to allow more capture and storage of CO2 when the algae is not growing as fast or during harvesting. Lower équivalent bicarbonate molarity allows CO2 absorption at lower pH, which accommodâtes more species. Each species and strain has an optimal pH and équivalent bicarbonate molarity range, and each has a different résistance to contamination. The rate of transfer across the gas-liquid interface is dépendent on the pH and équivalent bicarbonate molarity.
Thus, for each target species, strain, and cultivation system, there can be a separate optimal pH and équivalent bicarbonate set point.
[00107] In some embodiments, the algae cultivation system l includes one or more channels 2, 3, 28 having a total surface area of at least 100 square ft (fi2). In some embodiments, the algae cultivation system l includes one or more channels 2, 3, 28 having a total surface area of at least 100 ft2, or at least 200 ft2, or at least 500 fl2, or at least 1000 ft2, or at least 5000 ft2, or at least 7500 ft2, or at least 10,000 ft2, or at least 20,000 ft2, or at least 30,000 ft2, or at least 40,000 ft2, or at least 50,000 ft2, or at least 100,000 ft2, or at least 500,000 ft2 to less than 600,000 ft2, or less than 1,000,000 ft2, or less than 5,000,000 ft2, or less than 10,000,000 ft2, or less than 20,000,000 ft2.
11. Process control:
[00108| Referring to FIG. 14, in some embodiments, the algae cultivation system 1 is used in conjonction with a controller 39 and one or more process measuring devices 40 configured to monitor a process parameter (e.g., pH, dissolved oxygen content, atmospheric light întensity, nitrogen concentration, carbon dioxide concentration, turbidity, optîcal density, and biomass productivity, algae cultivation fluid height) in the algae cultivation system 1 and/or the algae cultivation fluid 12. In some embodiments, the process measuring devices 40 include one or more sensors configured in the algae cultivation System 1 or in the algae cultivation fluid 12. Nonlimiting examples of suitable sensors include pH sensors, a dissolved oxygen level sensor, a light întensity sensor, a level sensor, or combinations thereof. The pH sensor may be configured to monitor the pH of the algae cultivation fluid.
[00109] The controller 39, the one or more process measuring devices 40, the bore wave generator 11, the pump System 8a, 8b, and optionally an air blower or valve in the dîffusers 24 or air mixing devices 7 may be placed in electrical communication to send and receive electrical signais. Suitable connections may include transmitters that allow process signais, such as electrical signais, to be transmitted between the controller 39, the measuring devices 40, and the bore wave generator 11.
[00110] In some embodiments, the electrical signais may be transferred via a wired connection or through a wireless network connection. Other hardware éléments may be included in the process control system, for example, transducers, analog-to-digital (A/D) converters, and digital-to-analog (D/A) converters that allow process information to be recognizable in computer form, and computer commands accessible to the process.
[00111] The controller 39 includes a processor and a memory that includes software and data, and is designed for storage and retrie val of processed information to be processed by the processor. The processor may receive input data or process signais from the measuring devices 40 and the bore wave generator 11. The controller 39 may operate autonomously or semîautonomousiy, or may read exécutable software instructions from the memory or a computerreadable medium (e.g., a hard drive, a CD-ROM, flash memory), or may receive instructions via the input from a user, or another source logically connected to a computer or device, such as another networked computer or server. For example, the server may be used to control the bore wave generator 11 via the controller 39 on-site or remotely.
[001 12] The processor may process the process the signais to generate an output, which may take the form of a process control action. Example process control actions may include adjusting the bore wave frequency in the channels 2, 3, 28 using the bore wave generator 11 in response to measured values obtained from the one or more measuring devîces 40. The bore wave frequency, intensity or a combination thereof may be adjusted to alter and/or maintain a desired set point of one or more process parameter (e.g., maintain a desired pH, carbon dioxide concentration, nitrogen concentration, dissolved oxygen content).
[00113] In some embodiments, the bore wave frequency, bore wave intensity, and/or air mixing device intensity can be varied, so that higher or lower surface area and mixing are generated, e.g. încreasing the wave frequency to provide more carbon dioxide during the high productivity times and reducing the wave frequency during lower productivity perîods .
[00114] During high productivity, the algae utilize carbon dioxide at a sufficient rate such that the relative carbonate-bicarbonate-dissolved carbon dioxide concentrations in the algae cultivation fluid are not in equilibrîum and the partial pressure of carbon dioxide from the media is lower than in equilibrîum. In these high productivity perîods, the driving force for carbon dioxide absorption is greater than predicted from equilibrîum calculations. Also, in these perîods, carbon dioxide can be absorbed from the air at a pH lower than the equilibrîum pH. The effect of încreasing wave frequency during higher productivity perîods is magnified because much larger gas-liquid area and mixing are generated at the same time as a higher driving force is available for COî absorption. Varying the wave frequency thus increases the absorption rate wîth a lower total energy use.
[001 15] The pH of the media is increased by algae growth as CO2 is removed from the media. The pH is decreased as CO2 is absorbed from the atmosphère. Since the wave frequency provides a mechanism to control the absorption rate, the wave frequency can be used to maintain a spécifie pH during cultivation.
[00116] Nitrogen fixing algae remove dissolved nitrogen from the cultivation media creating a driving force for absorption of nitrogen from the air. Unlike carbon dioxide which can be stored within the algae cultivation fluid as bicarbonate for later use, nitrogen is only stored in a limited quantity as a dissolved gas. Typically, the stored quantity of dissolved nitrogen is not sufficient to supply the nitrogen needed for high productivity. Therefore, higher absorption rate îs required to support growth during high productivity perîods. By varying the wave frequency and/or air flow to the diffusers 24 to generate higher surface area and mixing during perîods of higher productivity, sufficient N? can be provided to support growth of nitrogen-fixing algae.
[001 17] An exampie method for varying the wave frequency or intensity is to utilise solar energy directly to provide power for the pump for wave génération. This will automatically increase the wave frequency or intensity during higher light intensity-higher productivity periods and reduce it during lower light intensity-lower productivity periods. Furthermore, it will reduce the cost of using solar energy to supply energy for the wave generator because the need for battery storage is greatly reduced compared to operating at a constant wave frequency. A small portion of the solar energy could be stored to provide a minimum level of mixing during very low light intensity or at night.
[00H8] in some embodiments, the controller 39 adjusts the bore wave generator 11 to release bore waves within the channels 2, 3, 28 at a wave frequency. In some embodiments, the frequency is adjusted by lifting the gâte 13 ofthe bore wave generator 11 at least every 10 seconds, or at least i 5 seconds, or at least 30 seconds, or at least 45 seconds, or at least every 60 seconds, to less 90 seconds, or less than 120 seconds, or less than 150 seconds, or less than 180 seconds, or less than 240 seconds, or less than 300 seconds. The gâte disp lacement rate may be used to control the bore wave frequency within the channels 2, 3, 28.
[00119] In some embodiments, the wave frequency, intensity or a combination thereof is adjusted using the bore wave generator 11 to maintain a desired pH of the algae cultivation fluid 12. In some embodiments, the one or more measuring device 40 is a pH sensor that monitors the pH of the algae cultivation fluid I2. In some embodiments, the wave frequency, intensity or a combination thereof is adjusted to maintain a desired pH of at least 9.5, or at least 9.8, or at least 9.9, or at least 10, or at least 10.1, or at least 10.2, or at least 10.3, or at least 10.4, to less than ! 0.5, or less than Ï0.6, or less than 10.7, or less than 10.8, or less than 10.9, or less than i l.
[00120] In some embodiments, the wave frequency, intensity or a combination thereof îs adjusted using the bore wave generator 11 to maintain a desired dissolved oxygen content. In some embodiments, the one or more measuring device 40 îs a dissolved oxygen content sensor that monitors the dissolved oxygen content of the algae cultivation fluid 12. In some embodiments, the wave frequency, intensity or a combination thereof is adjusted to maintain a desired dissolved oxygen content of at least 100% oxygen saturation, or at least 120%, or at least 140%, or at least 160%, or at least l 80% to less than 200%, or less than 300%, or less than 400%, or less than 500% oxygen saturation.
[00121] In some embodiments, the wave frequency, intensîty or a combination thereof is adjusted using the bore wave generator 11 to disrupt an air-liquid interface of the algae cultivation fluid 12 to induce direct absorption of atmospheric carbon dioxide from air into the algae cultivation fluid 12 such that a majority of the carbon in the algae and/or carbon dioxide dissolved in the algae cultivation fluid 12 is from the atmospheric carbon dioxide, or at least 55% is from atmospheric carbon dioxide, or at least 60%, or at least 65%, or at least 70%, or at least 75%, or at least 80%, or at least 85%, to less than 90%, or less than 95%, or 100% of the carbon dioxide îs from atmospheric carbon dioxide.
[00122] In some embodiments, the carbon content in the algae or the carbon dioxide content in the algae cultivation fluid 12 may be measured using methods known to the skilled artisan, such as a CHN analyzer or a gas sensing electrode (e.g., carbon dioxide sensîng electrode). In some embodiments, isotropie analysis may be used to carbon date the carbon in the algae or carbon dioxide în the algae cultivation fluid 12. This may be used to estîmate how much carbon in the algae or carbon dioxide dissolved în the algae cultivation fluid 12 is derived from atmospheric carbon dioxide versus other carbon sources (e.g., flue gas). For example, flue gas typically has an older carbon date relative to carbon dioxide derived from the atmosphère.
[00123] In some embodiments, the wave frequency, intensîty or a combination thereof is adjusted using the bore wave generator 11 to ma intain a minimum bicarbonate concentration obtained through the absorption of atmospheric carbon dioxide. In some embodiments, the wave frequency, intensîty or a combination thereof is adjusted to maintain a minimum bicarbonate concentration of at least 1 mM throughout the entire volume of the algae cultivation fluid 12, or at least 5 mM, or at least 10 mM, or at least 15 mM, or at least 20 mM, or at least 25 mM, or at least 30 mM, or at least 35 mM, or at least 40 mM, or at least 45 mM, or at least 50 mM, or at least 60 mM, or at least 70 mM, or at least 80 mM, or at least 90 mM, to less than 100 mM, or less than I 10 mM, or less than 120 mM, or less than 130 mM, or less than 140 mM, or less than 150 mM, or less than 160 mM, or less than 170 mM, or less than 1 80 mM, or less than 190 mM, or less than 200 mM, or less than 300 mM, or less than 400 mM, or less than 500 mM.
[00124] In some embodiments, the wave frequency, intensîty or a combination thereof is adjusted using the bore wave generator 11 to maintain an average équivalent bicarbonate concentration obtained through the absorption of atmospheric carbon dioxide. In some embodiments, the wave frequency, intensîty or a combination thereof is adjusted to maintain an average équivalent bicarbonate concentration of sodium ions of at least 1 mM throughout the entire volume of the algae cultivation fluid 12, or at least 5 mM, or at least 10 mM, or at least 15 mM, or at least 20 mM, or at least 25 mM, or at least 30 mM, or at least 35 mM, or at least 40 mM, or at least 45 mM, or at least 50 mM, or at least 60 mM, or at least 70 mM, or at least 80 mM, or at least mM, to less than 100 mM, or less than 110 mM, or less than 120 mM, or less than 130 mM, or less than 140 mM, or less than I50 mM, or less than 160 mM, or less than 170 mM, or less than l 80 mM, or less than 190 mM, or less than 200 mM, or less than 300 mM, or less than 400 mM, or less than 500 mM.
[00125] In some embodiments, an équivalent bicarbonate concentration of sodium ions in the algae cultivation fluid and the bore wave frequency, intensîty or a combination thereof are selected to maintain a différence between a maximum and minimum pH during day light hours of less than 0.8 pH units, or less than 0.7 pH units, or less than 0.6 pH units, or less than 0.5 pH units, or less than 0.4 pH units, or less than 0.3 pH units. As used herein, the term day light hours refers to one-half hour before an official sunrîse through one-half hour after official sunset ofthe région of operation.
[00126] In some embodiments, the wave frequency, intensîty or a combination thereof is adjusted using the bore wave generator 11 to disrupt an air-lîquid interface ofthe algae cultivation fluîd I2 to induce direct absorption of atmospheric nitrogen from air into the algae cultivation fluid 12 such that a majority of the nitrogen in the algae and/or dissolved in the algae cultivation fluid 12 is from the atmospheric carbon dioxide, or at least 55% is from atmospheric nitrogen, or at least 60%, or at least 65%, or at least 70%, or at least 75%, or at least 80%, or at least 85%, to less than 90%, or less than 95%, or 100% of the nitrogen is from atmospheric nitrogen. In some embodiments, the nitrogen content in the algae or the nitrogen content in the algae cultivation fluid 12 may be measured using methods known to the skilled artisan, such as a CHN analyzer or a gas sensing electrode (e.g., nitrogen sensing electrode).
[00127] In some embodiments, the wave frequency, intensîty or a combination thereof is adjusted using the bore wave generator 1 1 to maintain an average nitrogen concentration obtained through the absorption of atmospheric nitrogen. In some embodiments, the wave frequency, intensîty or a combination thereof is adjusted to maintain an average nitrogen concentration of at least 1 mg/mL, or at least 5 mg/mL, or at least 10 mg/mL, or at least 15 mg/mL, to less than 20 mg/mL, or less than 25 mg/mL, or less than 30 mg/mL.
[00128] In some embodiments, the wave frequency, intensîty or a combination thereof is adjusted using the bore wave generator i 1 based on an atmospheric light intensîty (e.g., increased during high light intensîty values, and decreases during low light intensîty values). In some embodiments, the one or more measuring device 40 is a light intensîty sensor configured to monitor the atmospheric light intensîty. In some embodiments, the wave frequency, intensîty or a combination thereof is adjusted from 10s to 300s based on measured atmospheric light intensîty values. For example, the wave frequency, intensîty or a combination thereof may be increased to a high frequency, intensîty or a combination thereof (e.g., from 10s to 100s) during high light intensity (e.g., from greater than 200 lux to 120,000 lux) and decreased (e.g., from 100s to 300s) during low light intensity (e.g., from 0.0001 luxto 200 lux).
[00129] In some embodiments, the wave frequency, intensity or a combination thereof is adjusted using the bore wave generator U based on a desired biomass productivity. In some embodiments, the biomass productivity is measured, and the wave frequency, intensity or a combination thereof is adjusted to maintaîn a desired set point. In some embodiments, the wave frequency, intensity or a combination thereof is adjusted to maintaîn a biomass productivity of at least 8 g/m2d, or at least 15 g/m2d, or at least 20 g/m2d, or at least 25 g/m2d, to less than 30 g/m2d, to less than 35 g/m2d, to less than 40 g/m2d, or to less than 45 g/m2d.
[00130] In some embodiments, the controller 39 may control a valve in the diffusers 24 to control the rate of diffusion of air into the algae cultivation fluid 12. In some embodiments, the controller 39 has programming stored therein to control the valve to flow air through the diffusers 24 as the bore waves pass over the air-liquid mixing devices 7, and cease air flow once the bore waves hâve passed over the diffusers 24. In some embodiments, the controller 39 has programming stored therein to control the valve to cease aîr flow through the diffusers as the bore waves approach the air-liquid mixing devices 7 (e.g., within 1 ft, or 2 ft, or 3 ft, or 4 ft, or 5 ft, or 10 ft, or 15 ft, or more), and résumé air flow once the bore waves move away from the diffusers 24 (e.g., at least 0 ft, 1 ft past, or 2 ft, or 3 ft, or 4 ft, or 5 ft, or 10 ft, or 15 ft, or more).
[00131] III. Method of use:
[00132] Referring to FIG. 15, a flow chart is provided illustrating an example method 100 of producing algae using an algae cultivation system 1. As indicated by step 102, the method 100 includes culturing algae in at least one channel 2 having a sloped bottom surface 6a, 6b, opposing side walls 5a, 5b, and an algae cultivation fluid 12 disposed in the at least one channel 2. The method 100 further includes applying bore waves through the algae cultivation fluid 12 at a bore wave frequency sufficient to disrupt an air-liquid interface of the algae cultivation fluid 12 to induce direct absorption of atmospheric carbon dioxide and/or nitrogen from air into the algae, as indicated in step 104. The method 100 may further include apply ing the bore waves through one or more air-liquid mixing device 7 configured within the at least one channel 2 to facîlitate direct absorption of the carbon dioxide and/or nitrogen into the algae cultivation fluid 12, as indicated in step 106. In some embodiments, the method 100 includes adjusting the bore wave frequency, intensity or a combination thereof to obtain or maintaîn a desired set-point for one or more process parameter within the algae cultivation system 1, as indicated in step 108. The method 100 may utilize the controller 39 to implement one or more process control action on any one of the algae cultivation Systems 1 described herein.
Examples
[00133] The following examples are presented by way of illustration and are not meant to be lîmiting in any way.
Inventive Example I :
[00134] Spirulina was cultivated in a 600 m2 raceway with supercritical waves traveling 1.1 m/s. The period for the waves was one every 1.25 minutes. Two cultivation conditions were tested. The first condition was cultivation at pH 9.5 with NaHCOs added daily to supply the CO2 for cultivation. The second was at pH 10.4 with no added CO2, so that ail CO2 for cultivation was from direct air capture. The productivity under the first condition averaged 11.8 g/m2d and the second condition averaged 12.1 g/m2d, so substantially the same productivity was achieved with and without added CO2.
Inventive Example 2:
[00135] Two sioped raceways were operated to cultivate Nitzschia sp. The équivalent bicarbonate concentration in the cultivation media was 0.3 molar in each raceway. The first raceway was operated at a pH of approximately 9.5, and bicarbonate media was used to supply the CO? for growth. The second raceway was operated at a pH of approximately 10.5 with a blower and a diffuser to supply air bubbles, and the only CO2 source for growth was the air. The productivity of the two raceways was tracked over 38 days. Fig. 16 présents a plot of the productivity in each ofthe raceways. The growth rate was similar in each raceway, and the average productivity for the 38 days for each raceway was between 22 and 23 g/m2d.
Inventive Example 3
[00136] Nitzschia was cultivated in 2m2 raceways simulating wave mixing with no paddlewheel at an average pH of about 10.4. The concentration of sodium ions added to the media as sodium carbonate varied from 0.01 molar to 0.3 molar. The productivity and pH were measured during cultivation without any added CO2, so that the ail CO2 for growth was supplied via direct air capture. Because CO2 ts absorbed in the day and night, but only consumed during the day, the pH varied from the lowest value in the early morning to the highest value in the afternoon. The pH swing is the différence between the highest and lowest pH. The following Table ! summarizes the results. Direct air capture with higher molarity sodium as sodium carbonate/sodium bicarbonate resulted in a higher productivity and smaller pH swing.
Table l.
Na+ molarity | Productivity (g/m2d) | pH swing |
0.01 | 3.8 | 0.83 |
0.03 | 5.3 | 0.66 |
0.1 | 7.6 | 0.50 |
0.3 | 11.2 | 0.37 |
Comparative Example 1 :
[00137] Spirulina was cultivated in a 1-acre raceway without waves at a pH of 10.5. The algal productivity with direct air capture without waves w'as found to be 4 g/m2d. For the same conditions in a large-scale raceway with the bore waves described in Inventive Example 1, the productivity was 12 g/m2d.
[00138] The invention has been described according to one or more preferred embodiments, and it should be appreciated that many équivalents, alternatives, variations, and modifications, aside from those expressly stated, are possible and within the scope of the invention.
[00 i 39] The preceding discussion is presented to enable a person skilled in the art to make and use embodiments of the invention. Various modifications to the illustrated embodiments will be readily apparent to those skilled in the art, and the generic principles herein can be applied to other embodiments and applications without departing from embodiments of the invention. Thus, embodiments of the invention are not intended to be limited to embodiments shown, but are to be accorded the widest scope consistent with the principles and features disclosed herein. The detailed description is to be read with reference to the figures, in which like éléments in different figures hâve like reference numerals. The figures, which are not necessarily to scale, depîct selected embodiments and are not intended to limit the scope of embodiments of the invention. Skilled artisans will recognize the examples provîded herein hâve many useful alternatives and fal 1 within the scope of embodiments of the invention.
[00140] It is to be understood that the disclosure is not limited in its application to the details of construction and the arrangement of components set forth in the description or illustrated in the drawings. The disclosure is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and équivalents thereof as well as additional items. Unless specîfled or limited otherwise. the terms “mounted,” “connected,” “supported,” and “coupled” and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplîngs. Further, “connected” and “coupled” are not restricted to physical or mechanical connections or couplîngs.
Claims (26)
- l. A method comprising the steps of:culturing aigae in at least one channel having a bottom surface, opposîng side walls coupled to the bottom surface, and an aigae cultivation fluid disposed in the at least one channel; and applying bore waves through the aigae cultivation fluid at a bore wave frequency sufficient to disrupt an air-liquid interface of the aigae cultivation fluid to induce direct absorption of atmospheric carbon dioxide or atmospheric nitrogen from air into the aigae cultivation fluid, wherein a majority of the carbon or nitrogen in the aigae is from the atmospheric carbon dioxide or atmospheric nitrogen.
- 2. The method of claim l, wherein the bottom surface of the channel is sloped.
- 3. The method of claim 2, wherein the si ope of the bottom surface is less than 0.5%.
- 4. The method of claim l further including passing the bore waves through one or more air-liquid mixing device configured within the at least one channel.
- 5. The method of claim 4, wherein the at least one channel includes from one airliquid mixing device for every 300 ft2 of surface of the at least one channel to one air-liquid mixing device for every 400,000 ft2 of surface of the at least one channel.
- 6. The method of claim 4, wherein one or more the air-liquid mixing devices are powered by the flow ofthe bore wave.
- 7. The method of claim 4, wherein a rate of air-liquid mixing is adjusted during the cultivation to reduce the energy consumptîon.
- 8. The method of claim 7, wherein solar energy is used to power the one or more airliquid mixing device, and wherein a rate of air-l iquid mixing is greater during times of higher solar radiation relative to times of lower solar radiation.
- 9. The method of claim 4, wherein the air-liquid mixing device générâtes aîr bubbles in the aigae cultivation fluid.
- 10. The method of claim 9, wherein a bubble génération rate is increased when the bore wave passes the air-lîquid mixing device, and is decreased during a period in between the bore waves.
- 11. The method of claim l, wherein the at least one channel has a surface area of at least 100 ft2.
- 12. The method of claim l, wherein the at least one channel has a surface area from 10,000 ft2 to 20,000,000 ft2.
- 13. The method of claim I, wherein the bore wave frequency, intensity, or a combination thereof is adjusted to obtain a minimum bicarbonate concentration in the algae cultivation fluid from l mM to 150 mM.I4. The method of claim l, wherein the bore wave frequency, intensity, or a combination thereof is adjusted to obtain a minimum bicarbonate concentration in the algae cultivation fluid from 10 mM to 150 mM.
- 15. The method of claim 14, wherein an équivalent bicarbonate concentration of sodium ions in the algae cultivation fluid is 10 mM to 500 mM.
- 16. The method of claim ], wherein an équivalent bicarbonate concentration of sodium ions in the algae cultivation fluid and the bore wave frequency are selected to maîntain a différence between a maximum and minimum pH during day light hours of less than 0.8 pH units.
- 17. The method of claim l, wherein an équivalent bicarbonate concentration of sodium ions în the algae cultivation fluid and the bore wave frequency are selected to maîntain a différence between a maximum and minimum pH during day light hours of less than 0.5 pH units.
- 18. The method of claim l, wherein the bore wave frequency, intensity, or a combination thereof is adjusted to maîntain a pH in the algae cultivation fluid of less than 11.
- 19. The method of claim l, further adjusting bore the wave frequency, intensity, or a combination thereof to maîntain a pH in the algae cultivation fluid of less than 10.6.
- 20. The method of claim l, further adjusting bore the wave frequency, intensity, or a combination thereof to maintain a pH in the algae cultivation fluid of less than 10.2.
- 21. The method of claim l, wherein the bore wave frequency is adjusted by displacîng a gâte in a bore wave generator.
- 22. The method of claim 21 further including displacîng the gâte at a frequency from10 seconds to 300 seconds to apply the bore waves through the algae cultivation fluid.
- 23. The method of claim l, wherein the bore wave intensity is adjusted by a height of the algae cultivation fluid behind a gâte in a bore wave generator.
- 24. The method of claim 23, wherein the height of algae cultivation fluid is adjusted by a rate of fi11ing of an area behind the gâte with algae cultivation fluid.
- 25. The method of claim l further including measuring at least one process parameter; and adjusting the bore wave frequency, intensity, or a combination thereof based on the at least one parameter or rate of change of the at least one parameter.
- 26. The method of claim 25, wherein the at least one process parameter is selected from the group consisting of a pl-l, a dissolved oxygen content, a bicarbonate concentration, a nitrogen concentration, solar intensity, algae growth rate, turbidity, optical density, and température.
- 27. The method of claim 25 further including adjusting the bore wave frequency, intensity, or a combination thereof to maintain a desired set-point of the at least one process parameter.
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US63/038,021 | 2020-06-11 |
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