Title of Invention	A PHOTO BIO-REACTOR FOR CULTIVATING AND HARVESTING A BIO-MASS AND A METHOD THEREOF
Abstract	The present invention relates to a photo bio-reactor for cultivating and harvesting a bio-mass suitable for producing hydrocarbon comprising: (i) a helical tubular system having a plurality of substantially coaxial helical transparent tubular coils(l,..), which could be easily autoclaved, for flow of a culture medium containing micro algae to be cultivated, each coil being hydraulically connected to its adjacent coaxial coil, said coils having annular spaces interposed between the adjacent coils and a space enclosed by the inner diameter of innermost coil, the first and the last coil each having a free end; (ii) a means (2) of providing periods of light and darkness on each point alternately for predetermined time periods on the inner and outer surfaces of each of said coil; (iii) a de-gasser chamber (4) having hydraulic connection with said free end of first coil (1) for removing unwanted gases from said culture medium; (iv) optionally, a stirrer (5) or 'perfusion air-lift reactor' (5) provided in said de-gasser chamber(4) for keeping the bio-mass in suspension in said culture medium; (v) said de-gasser chamber (4) having hydraulic connection with a heat exchanger (6) for controlling temperature of said culture medium; (vi) a means (7) for causing flow of said culture medium in said coils without said means coming into direct contact with said medium; and (vii) a gas injection means (8) connected to said de-gasser chamber (6) on one end and said free end of last coil on the other end.

Title of Invention

A PHOTO BIO-REACTOR FOR CULTIVATING AND HARVESTING A BIO-MASS AND A METHOD THEREOF

Abstract

The present invention relates to a photo bio-reactor for cultivating and harvesting a bio-mass suitable for producing hydrocarbon comprising: (i) a helical tubular system having a plurality of substantially coaxial helical transparent tubular coils(l,..), which could be easily autoclaved, for flow of a culture medium containing micro algae to be cultivated, each coil being hydraulically connected to its adjacent coaxial coil, said coils having annular spaces interposed between the adjacent coils and a space enclosed by the inner diameter of innermost coil, the first and the last coil each having a free end; (ii) a means (2) of providing periods of light and darkness on each point alternately for predetermined time periods on the inner and outer surfaces of each of said coil; (iii) a de-gasser chamber (4) having hydraulic connection with said free end of first coil (1) for removing unwanted gases from said culture medium; (iv) optionally, a stirrer (5) or 'perfusion air-lift reactor' (5) provided in said de-gasser chamber(4) for keeping the bio-mass in suspension in said culture medium; (v) said de-gasser chamber (4) having hydraulic connection with a heat exchanger (6) for controlling temperature of said culture medium; (vi) a means (7) for causing flow of said culture medium in said coils without said means coming into direct contact with said medium; and (vii) a gas injection means (8) connected to said de-gasser chamber (6) on one end and said free end of last coil on the other end.

Full Text	Field of Invention This invention relates to a PhotoBioreactor for cultivation of Botryococcus braunii and a method for efficiently growing the microalgae. More particularly, the invention relates to a PhotoBioreactor and method for cutivation of biomass for producing bio-diesel. The bioreactor and the method can be adapted to production of other microalgae including spirulina. Botryococcus braunii, is a highly rich renewable source of hydrocarbons. The high cost of known microalgal culture systems relates to the need for light and the relatively slow growth rate of the algae. The photobioreactors must be designed keeping in mind that light is needed continuously for microalgal cultures. Since the intensity of light decreases rapidly with the depth of the culture, the geometry of the reactor is equally important. Important concern is to reduce the costs of these systems further to make them economically competitive. Bioreactor System design depends on organism property, media property and system kinetics. The property of the organism is important because we need the organism to grow in the desired fashion so that the acclaimed metabolic route is followed to yield us the preponderance of desired product. Factors such as Oxygen / Carbon Dioxide dependency play crucial role, hence the importance of the size of the bubble and the time it spends in the liquid column. We also need to take care of the hydrodynamic shear since the growth may decrease sharply after increase of gas flow rate beyond certain value due to cell damage. Cell damage is dependent on the strain used, the bubble size based on the nozzle because smaller nozzle, which produce smaller bubbles, are more detrimental. But there is advantage of having smaller nozzle as it gives in more diffusion of the gas in the medium, and hence we need to make an optimum choice. Thus there is a need of proper sparger. In general superficial air velocity of 0.085 m/s can be considered the upper limit beyond which organism without cell wall can undergo damage. In case of scale up, when more quantity of gas is required, we must assure either increasing the number of nozzles or increasing the diameter does not exceed this velocity. Algae use light as an energy source and obtain all the carbon they need from inorganic sources (CO2) and are thus photoautotroph. Micro algal biotechnology has the potential to produce a vast array of products including foodstuffs, industrial chemicals and compounds with therapeutic applications, bioremediation solutions and hydrocarbons. Background Art Oak Ridge National Laboratory and Ohio University have been demonstrating the and biomass production in photobioreactors using sunlight. Large solar collectors on the roof track the sun, collect sunlight, and distribute it through large optical fibers to the bioreactor's growth chamber. The fibers function as distributed light sources to illuminate cyanobacteria (algae). Each growth chamber consists of a series of illumination sheets containing the optical fibers and moist cloth-like membranes on which the algae grow. By stacking the membranes vertically and better distributing the light, more algae can be produced via photosynthesis in a smaller area.Ohio University photobioreactors use sunlight to sequester carbon from coal-fired power plants as they produce biomass.A drawback of this system is that in horizontal cultivator systems, light penetrates the suspension only to 5 cm, leaving most of the algae in darkness. The top layer of algae requires only about 1/10th the intensity of full sunlight to maximize growth, so the remaining sunlight is wasted. James C. Ogbonna and Hideo Tanaka have developed a prototype photobioreactor consisting of four units built with 0.5-cm-thick transparent Pyrex glass for the cultivation of C. pyrenoidosa. Each unit was equipped with a centrally fixed glass tube into which the light source was inserted. Transparent glass tubes were used as housings for the lamps, so the reactor was illuminated by simply inserting the lamps into the glass tubes (no mechanical fixing). Any light source could be used. Either 4-W fluorescent or halogen lamps with controllable light intensity were used as the illuminating system. Because the lamps are not mechanically fixed and can easily be replaced, the same reactor can be used for efficient cultivation of various cells by using a light source with controllable light intensity or by simply replacing the light source with one that gives the desired light intensity. For mixing, an impeller modified in shape is used so that it did not touch the glass housing unit during rotation. United States Patent 5,614,378 (Yang , et al, March 25, 1997) discloses a photo bio reactor comprising a hollow, cylindrical irradiation chamber, wherein said chamber comprises a top sealed to a cylindrical side wall; a bottom sealed to said cylindrical side wall; said top, bottom and cylindrical side wall together enclosing a cylindrical space; a first cylindrical light irradiator disposed in said cylindrical space and attached only to said top; and a second cylindrical light irradiator disposed in said cylindrical space and attached only to said bottom; wherein all cylindrical light irradiators and said cylindrical side wall are coaxial; the distance between said cylindrical side wall and cylindrical light irradiator closest to said side wall is within 1 mm to 20 cm, and the distance between each adjacent cylindrical light irradiator is within 1 mm to 20 cm, for a time sufficient to produce said biologically-active compound, while irradiating said cells with said first light cylindrical irradiator and said second light cylindrical irradiator. This photo bioreactor may also be used in a method to fix carbon dioxide, to produce, e.g., fuels and/or chemical feed stocks. In this application, the cultured cells are suitably, e.g., Botryococcus braunii. United States Patent 4,952,511 (Radmer , August 28, 1990) teaches a photo bio reactor which comprising a tank for containing a liquid microbial culture; a high-intensity light source whose light is substantially entirely directed into a light compartment; said light compartment having at least one transparent wall extending into said tank; and said light compartment containing a tube of internally reflective prismatic sheet, said tube extending substantially from said light source to an end wall of said light compartment opposite said light source and said tube having transverse dimensions sufficient to substantially surround said light source, said tube further including a mirror at the end thereof opposite said light source oriented to reflect light back into said tube, wherein the light source, the tube and the mirror are arranged, so as to distribute light from said highintensity light source substantially uniformly across the interior surface of the transparent wall of said light compartment. United States Patent 5,137,828 (Robinson , et al. August 11, 1992) teaches an apparatus comprising an upstanding substantially cylindrical support structure; a substantially transparent tube supported by the support structure and wound helically on the outside thereof so that, in use, the exterior of the wound tube is exposed to natural light, said tube containing at least living plant matter; a header tank at the top of the support structure, the upper end of the transparent tube being connected to the header tank; a pipe extending from the header tank to the bottom of the support structure, said pipe being connected to the lower end of the transparent tube; means for causing a synthesis mixture to flow under turbulent conditions through the tube, the header tank and the pipe; and means for withdrawing a biomass synthesis product from at least one of the header tank and the wound tube. United States Patent 4,724,214 (Mori February 9, 1988) discloses an apparatus for photosynthesis comprising bath means containing a photosynthetic reaction bath, a plurality of tubular photoradiators arranged upright in said bath means in parallel array, upper support means and lower support means in said bath means for supporting the upper and lower end portions respectively of said tubular photoradiators, said tubular photoradiators being spaced from one another so as to define a plurality of upright passages between said tubular photoradiators, said upper support means closing off the upper ends of said upright passages, said bath means having a lower chamber underlying said lower support means, said lower support means having a flow-through portion which provides communication between said chamber and a first plurality of upright passages and a stopped up portion which blocks communication between said chamber and a second plurality of upright passages, conduit means leading to said chamber for supplying CO2 -containing air, said flow-through portion and said stopped up portion of said lower support means being constructed and arranged such that said air passes from said chamber through said flow-through portion into said first plurality of upright passages, said air passing upwardly in said first plurality of upright passages and subsequently being directed generally laterally by said upper support means such that the air then passes downwardly in said second plurality of upright passages to subsequently again be directed generally laterally by said stopped up portion of said lower support means to once again pass upwardly in said first plurality of upright passages, whereby the air circulates in said bath means between said tubular photoradiators. United States Patent 4,676,956 (Mori June 30, 1987) teaches an apparatus for photo synthesis comprising a reaction bath means for causing a photosynthetic reaction therein, said reaction bath means comprising an inner transparent wall and an outer transparent wall surrounding and spaced from said inner transparent wall to define an annular space between the inner and the outer transparent walls, the inner and outer transparent walls being generally vertically disposed, and a light source positioned radially inwardly of the inner wall; a plurality of narrow tubular photoradiators arranged upright in said annular space parallel to each other, each of said photoradiators being constructed to radiate light which propagates therethrough; and a disc rotatable in a horizontal plane below the reaction bath means and disposed perpendicular to the photoradiators to eject jets of carbon dioxide-containing air into the annular space. Japanese Patent JP7023767 provides a culture tank opened at one end provided with a fixing plate having plural holes to close the open end of the culture tank. Plural protection tubes made of a transparent material and each having an insertion opening at one end and closed at the other end are fixed to the fixing plate parallel to each other by bonding the circumference of each hole to the outer circumference of the insertion opening. The fixed tubes are put into the culture tank. A rod light-source is removably inserted into each protection tube and a lid is applied to the fixing plate at the side opposite to the side holding the protection tubes. The circumference of the opening of the culture tank 10 is detachably fixed to the circumference of the fixing plate in liquid-tight state with an engaging means to provide this photo- bioreactor. Japanese Patent JP9009953 teaches a method to obtain a new Botryococcus braunii B race strain producing hydrocarbons mainly consisting of 30-33C hydrocarbons and containing above a specific weight ratio of a 30C hydrocarbon to the total of hydrocarbons. Planktons on the surface of Ippeki lake (Shizuoka prefecture) are collected by using a Kitahara type plankton net with 25u. m mesh. The prepared specimen is observed by a microscope and a colony of an alge of the genus Botryococcus is collected. The colony is cultured in a test tube, a single colony of the alga of the genus Botryococcus is raked by a platinum wire while observing characteristic properties of the alga of the genus Botryococcus in a colony state, etc., by using a stereoscopic microscope and cultured in a float plate medium to give a new Botryococcus braunii B race strain which produces hydrocarbons consisting mainly of 30C to 33C hydrocarbons and containing >=5wt,% 30C hydrocarbon based on the total of hydrocarbons and is Botryococcus braunii SI-1 strain. Japanese Patent JP9234055 recites a method for efficiently culturing the strain of fine algae belonging to the genus Botryococcus braunii A race capable of producing a 33C hydrocarbon. A hydrocarbon produced by the alga of this strain contains a 33C hydrocarbon. The new strain of the fine alga belonging to the genus Botryococcus braunii A race is cultured under intermittently irradiating the strain with an artificial light preferably once daily for 5-15 hours. Japanese Patent JP9173050 method for efficiently culturing a microalgae belonging to green algae, which has ability to fix CO2 by light energy and converts it into useful substances such as fuel comprises culturing microalgae (e.g. Botryococcus braunii CCAP807/1, etc.) belonging to such as Botryococcus, Chlorella, or Haematococcus, which belongs to green algae, while adding intermittently a disinfectant such as hypochlorous acid, hypochlorite, hydrogen peroxide and ozone to the culture medium intermittently each in a quantity of 0.01-200ppm so as to attain an effective quantity of the disinfectant in an open system under conditions of light illuminance and aeration of 0.05-5wm air containing CO2 in concentration of 0.03-30% at culturing temperature of 10-4°C for about 10 days. Accordingly, various types of Biorectors known in the art are described along with draw backs in the following paragraphs. A common CSTR type reactor, which is externally illuminated by light source. This has a poor surface to volume value and since the illumination is from outside, a major part of light energy is wasted and inefficiently utilized. A common lab scale reactor provides high light supply capacity and can be illuminated by both artificial and solar light. However, this has a poor surface to volume value and so a large number of light tubes would be required and thus would be energy consuming, a factor very detrimental for scale up. A Flat Plate reactor derives the laminar concept from plants. If light energy has to be available continuously to the cells, a lamination of photobioreactor directed to the light source seems to be the best solution. Apart from the high surface/volume value offered in case of tubular reactors, plate-type reactors have some advantages with respect to compactness. The advantages of a flat plate photobioreactor include easy introduction of turbulence, easy approachability of inner walls, providing easy control of wall growth and fouling and they may be tilted towards sun, ensuring higher absorption of incident energy. However, there is a major demerit of problems faced when attempting to scale-up since a corresponding increase in width would lead to a reduction of light intensity in the inner section of the reactor. In a typical airlift reactor, mass transfer is high and short liquid circulation time can be obtained. Further there is insignificant hydrodynamic stress. The riser can comprise of the dark zone and the down comer as photic zone. Airlift operation uniformly suspends microplantlets and improves exposure to light. Also there is continuous addition of nutrient medium and high cell density would be obtained in matter of time such that biomass is retained within vessel. Possibly modification include introducing alternating dark and transparent section in the inner column to take into account of organism specific flashing light effect. However, if the light source is from outside then there would be major loss in the energy. One of the most promising closed tubular photobioreactors design is the helical reactor. Tubular systems are generally arranged in a Horizontal serpentine form and made of glass or plastic tubes. Recirculation of culture suspension can be obtained by airlift technology or by means of pump. Floating or submerging the tubes on or in a pool of water controlled temperature, oxygen degassing being guaranteed by flexible tube elements. Biocoil is an arrangement of coiled polyethylene tubes of about 30-60 mm diameters around an open circular framework. Helical tubular photobioreactor is advantageous because it allows a larger ratio of surface area to culture volume to receive illumination effectively, thereby reducing the selfshading phenomenon. Thus there is improved light transfer since the tube diameter has short light path to reduce light attenuation through culture suspension However this reactor has a drawback that upscaling involves large area for a given biomass production. Objects of Present Invention The principle object of the present invention is to propose a photo bioreactor for efficiently growing the microalgae Botryococcus braunii with an enhanced growth rate than obtained by bioreactors known in the art. Another object of the present invention is to propose a method efficiently growing the microalgae Botryococctts braunii with an enhanced growth rate than obtained by the methods known in the art. Yet another object of the present invention is to propose a bioreactor and method which is simple and economical to implement. Other objects and advantages of the present invention will be clear from the description, examples, claims and drawings which follow. Statement of Invention: According to one aspect of the invention there is provided a photo bio-reactor for cultivating and harvesting a bio-mass suitable for producing bio-diesel comprising: (i) a helical tubular system having at least two substantially coaxial helical transparent autoclavable tubular coils for flow of a culture medium containing micro algae to be cultivated, said coils being at least a first coil and at least a last coil, each coil being hydraulically connected to its adjacent coaxial coil, said coils having annular spaces interposed between the adjacent coils and a space enclosed by the inner diameter of innermost coil, the first and the last coil each having a free end; (ii) a means of providing periods of light and darkness on each point alternately for predetermined time periods on the inner and outer surfaces of each of said coil;(iv) a de-gasser chamber having hydraulic connection with said free end of first coil for removing unwanted gases from said culture medium; (v) optionally, a stirrer provided in said de-gasser chamber for keeping the bio-mass in suspension in said culture medium; (vi) said de-gasser chamber having hydraulic connection with a heat exchanger for controlling temperature of said culture medium; (vii) a means for causing flow of said culture medium in said coils without said means coming into direct contact with said medium; and (viii) a gas injection means connected to said de-gasser chamber on one end and said free end of last coil on the other end. According to another aspect of the invention there is provided a method of cultivating and harvesting a bio-mass in a photo bio-reactor as claimed in claim 1, comprising the steps of: (a) circulating a culture medium containing a micro algae in said reactor at a predetermined flow rate; (b) providing alternately period of light and darkness for predetermined time periods on each point along the flow path of said circulating culture medium; (c) removing unwanted gases from said circulating culture medium; (d) controlling temperature of said culture medium between 25° and 36° C; (e) optionally, stirring said circulating culture medium to keep said micro algae in suspension; (f) injecting CO2 and air into said circulating culture medium to ensure a predetermined gas flow rate; (g) providing continuous darkness for a predetermined time period on each point along the flow path of said circulating a culture medium; and (h) harvesting cultivated micro algae from said circulating culture medium. Brief Description of Accompanying Drawings Figure 1. shows the photobioreactor. Figure 2. shows the cage around which the helical coil is wound. Figure 3. shows the growth profile of B. braunii at 31 °C Figure 4. shows the hydrocarbon content profile of of B. braunii at 31 °C Figure 5. shows the growth profile of B. braunii at 27 °C Figure 6. shows the hydrocarbon content profile of of B. braunii at 27 °C Detailed Description The ability of photoautotrophic microbes to make use of solar energy for metabolism is dependent upon the effective surface area of the rays to which it is subjected, which reduces with increase in population. As opposed to heterotrophic microorganisms where mixing solves the distribution of the organic molecules as energy carriers by mixing, the supply of photons is based on the surface area. Light gradient would always tend to occur due to mutual shading of the cells and light absorption. The light intensity in a photobioreactor decreases exponentially with the depth. Since the intensity of light decreases rapidly with the depth of the culture, the geometry of the reactor is equally important. High alteration between subjecting to light regime and dark regime in the order of microseconds to up to a second results in enhancement of photosynthetic efficiency. It has been observed that turbulence in an optically dense culture increases the efficiency of light utilization by photosynthesis. This effect is denoted as a flashing light effect. This effect is due to the fact that photosynthesis does not cease at the instant when light is removed but continues until the energy absorbed in the prior light period has been used and chemically stored. Short cycle time flashing light effect could be a result of fast effect of electron acceptors associated with the photo-system II followed by their oxidation in the dark period. In turbulence, individual cells are subjected to a pattern of light and dark periods. The flashing light effect could thus increase photo-accepting capacity. The subjection of Light & Dark regime should not be in the order of seconds, as it would then lead to reduction in photosynthetic activity resulting in reduced biomass yield. But the exact order of the Light/Dark value depends on the organism of choice and the product required. However, it is evident that this Light/Dark cycle will determine the efficiency and productivity that we desire for a given compound. Algal culture is in light demand through antenna pigments in the cell. Antennas that are damaged need a recovery time. Helical tubular bioreactor facilitates temperature control and restricts contaminants because it is a closed bioreactor. There is better CO: transfer from the gas stream to the liquid culture medium due to the extensive CO2 absorbing pathway. Possibly, a modification may include introducing alternating dark and transparent section in the inner column to take into account of organism specific flashing light effect. Its disadvantages include requirement of a large land area for a given volume. Another aspect is that the system is suitable only for disperse culture suspension as pump action disperses cell clumps. Some factors that influence the light requirement of an algae culture are: /. Type of algae culture and optimum wavelength: The Light requirement of algae depends on the major pigment present on the algae. Different pigments absorb light in different range of wavelengths; chlorophyll a in the range of 400-450 nm (between Violet and Blue) and around 680nm(Red), p-carotene 400-500 nm (Violet to Green), chlorophyll b (400-500nm). Further we also need to remember that energy delivered is inversely proportional to the wavelength, but the penetration is directly proportional to the wavelength. In Green algae Chlorophill a, Chlorophill b and (3-carotene are light harvesting pigments which have their absorption wavelength maxima in the range 400nm-500nm and 620-680nm. 2. Type of Light source: Some of the efficient light sources from the electric consumption and wavelength requirement point of view are Light Emitted diodes (LEDs), Fluorescent lights, and incandescent/halogen lamps. Fluorescent lamps are used most frequently for the cultivation of phototrophic organisms. The emission wavelength emitted from the mercury vapor can be converted to continuous radiation by modifying the composition of the fluorescent material, which allows for an optimum spectrum of photosynthesis. LEDs are one of the most efficient one in converting electricity to light with desired wavelength. However, if broader wavelength is required then combination of LEDs has to be used. We also need to keep into account the increase in wavelength due to absorption of rays as Heat energy. 3. Intensity of Light source: The light intensity at which the cell growth begins is called the compensation intensity (Ic) and the light intensity after which no further increase in growth takes place with increased light intensity is called the saturation intensity (Is). After a certain more increased value of light intensity, decrease in specific growth rate starts to takes place. This phenomenon is called photoinhibition and the intensity is denoted (Id). Further, the values of Ic, Is and Id is strain and temperature dependent. The specific growth rate of algae increases linearly with light intensity up to the saturation light intensity, thereafter-light inhibition is observed. Generally, the Is increases as the temperature is increased resulting in increased specific growth rate. In general, the helical system bioreactors prove to be better than the stirred system. This can be attributed to large dark volume characterized by cylindrical reactors. This dark volume can be taken care by inserting transparent pipes into the cylinder from the top through holes in the lid, holding fluorescent tubes, such that it can easily be removed during sterilization. T-shaped multifunctional stirrer is used to agitate the suspension and to supply sterile air. The denser is the culture of micro algae, the more problematic is the light penetration, and extremely limited. This restricts the commercial production to just flat plate photobioreactor and narrow bore tubular reactor. In spite of the efficient performance of thin channel flat plate types of photobioreactors, there is difficulty in scaling it up for production of significant quantities of product. This further limits our choice to tubular photobioreactor. The major disadvantage of tubular reactors is that for the same amount of volume, the area required is much more in comparison to other reactors. Other possibilities comprise of bubble column and airlift reactors that are more compact than tubular devices and can be deployed if a certain loss of productivity is acceptable. From Commercial point of view, a PBR must have high productivity, large volume, low maintenance and building expenses, and flexibility and ease to control culture parameters. Use of Immobilized Algal Cells Immobilized cell culture offers important advantages over free suspension in particular when the cells are slow growing. Extra-cellular products can be recovered continuously with ease. Since micro algae are shear sensitive, immobilization can protect cells against hydrodynamic shear forces. Immobilization by Calcium Alginate beads results in cells with enhanced chlorophyll content in attempt to capture more of the available light. Gelentrapped cells are thus protected from photoinhibition, a condition in which intense irradiance actually causes a loss in photosynthetic performance. However, Alginate gelimmobilized cells have a lower growth rates and lower biomass production relative to free controls, possibly because immobilization can reduce availability of substrate to the cells. It is to be noted that Immobilized cells retain the ability to produce hydrocarbons, whose structure and relative abundance are not affected by immobilization. PUF (Polyurethane Foams) support matrices have broad range of porosity and mechanical strength. However, the exposure to light to the cells drops down noticeably and so does the growth. Cotton gauze - immobilized B. braunii cells show higher levels of hydrocarbon production, biomass growth, and photosynthetic activity when compared with cells immobilized in PUF. Despite advantages, the practicability of immobilized algal culture remains questionable unless the cells can be cultured in long-duration continuous culture and the hydrocarbons can be extracted continuously, say by doing some protein engineering for post-translational modification in the corresponding DNA sequence, or by selectively subjecting the beads to extracting solvent such that the hydrocarbon is extracted and the cell remains as it is inside the beads. B. braunii has a disperse culture growth and growth into clump-form is not an advantage to the organism, rather causes reduction in the supply of oxygen to the inner cells. Hence application of Tubular coiled reactor is advantageously is the best for the purpose. High surface to volume value is desired for more or less equal distribution of light intensity. Hence application of Tubular coiled reactor serves best for the purpose. hi a preferred embodiment, to introduce proper Flashing light effect for the organism B. braunii dark strips of appropriate width are introduced at regular intervals, such that the order is not more than a second. For maximum utilization of energy, light is provided from inside and not from outside, such as inside the coiled helix in the Tubular coiled reactor. To ensure better distribution of light, straight tube-lights may be preferred over bent 'U' shaped tube-lights. Light of appropriate wavelength must be used which is optimum for B. braunii. Typically in Green algae Chlorophill a, Chlorophill b and 6- carotene are light harvesting pigments which have their absorption wavelength maxima in the range 400nm-500nm and 620-680nm. Either single fluorescent light can be deployed covering the entire wavelength of 400-700nm, or 2 LEDs can be made use of, one with the emission bandwidth of 400-500nm and another with 600-700 nm as LEDs have a narrow bandwidth. The choice would be governed by comparative economics.Light intensity is kept to be around saturation intensity, as an increase further would lead to decrease in growth rate and wastage of energy. Use of Solar-Light and optical fibre can be deployed since in a Tropical country such as India there is abundant supply of solar energy. Care is taken to ensure appropriate and more-or-less uniform temperature as the saturation intensity changes with change hi temperature, and would thus lead to errors in observation. In general superficial air velocity of 0.085 m/s can be considered the upper limit beyond which organism without cell wall can undergo damage. Since each cell of B. braunii has its own cell wall, we can operate at values above this numerical figure, but at the same time the value should not be very high as micro algae are known to be shear sensitive. The Carbon-Dioxide percentage of 5% can be considered to be optimum for microalgae growth though the exact optimum value would be dependent on other factors such as the strain & temperature. Tubular Helical PBR takes into account of most of the above considerations. The only demerit is the large land area required for scale up as for a given volume the coiled tube would be very long . The present invention nullifies this effect and thereby reduces the problem of large land area. In an embodiment, a peristaltic pump is provided it is not harmful for the shear-sensitive organism such as the B. Braunii. Usage of pump also reduces the chances of reverse flow. Additionally, the pump action also disperses cell clumps and thereby facilitates more of absorption of nutrients and light by individual cells. Care should be taken that pressure of the medium being pumped does not exceed the osmotolerance pressure which is 1 atmosphere (guage). The present 'Flash Light Super Helical Photo Bio Reactor' takes care of the scalability issue of traditional helical photobioreactor and also introduces increase in the photosynthetic activity of the microalgae by Flash-Light effect. A preferred embodiment of the bio-rector comprises a helical tubular system having at least two substantially coaxial helical transparent autoclavable tubular coils(l) for flow of a culture medium containing micro algae to be cultivated, each coil being hydraulically connected to its adjacent coaxial coil, said coils having annular spaces interposed between the adjacent coils and a space enclosed by the inner diameter of innermost coil, the first and the last coil each having a free end. The number of coaxial coils may be 2 or 3 or more. The end of each coil is hydraulically connected to the starting point of adjascent coil. The primary requirements of the tube forming superhelical structure is that it should be transparent and autoclavable. Further, it should be non-fragile and economical. One possibility was that of Glass. Though glass satisfies the first two criteria extremely well, it is highly delicate and mishandling or accidental touch can destroy the entire setup. Further, the cost of fabrication using Glass for the above scheme turns out to be extremely high. More importantly, the brittle and fragile nature of glass makes it incapable to tolerate high guage pressure over an extended period. Lastly, there is constraint on the fabrication in limiting the gap distance between any two adjacent rings to be not less than a centimeter, which reduces the compactness and thereby the scalability. In a preferred embodiment, pipe material used which is resistant to heat and is autoclavable is transparent type Silicone Tube. Though the transparency of Silicone is not as good as that of a Glass, silicone is flexible, non-fragile, autoclavable and costs almost half of what it costs for fabrication using Glass. The photostage of present invention comprises said transparent autoclavable tubular coils made from silicon polymer material. The bio reactor has a means(2,3) of providing Flash-Light effect i.e. periods of light and darkness on each point alternately for predetermined time periods on the inner and outer surfaces of each of said coil. In a preferred embodiment means(3) for providing periods of light is a plurality of tubelights uniformally placed in the annular space between two adj ascent coils and the space enclosed by inner diameter of the innermost coil. In another embodiment, a plurality of light emitting diodes is used for this purpose. An optic fiber coil may be used to provide solar illumination in another embodiment. In another embodiment, a combination of these means are used. In a preferred photo bio-reactor means(2) of providing period of darkness comprises a plurality of opaque strips or wires of predetermined width or diameter which obstruct the light from means of illumination falling on various points along the surface of the helical tubular coils and thus provide periods of light and darkness for the culture medium circulating in the helical tubular coils. In a preferred photo bio-reactor said alternating light and darkness time periods on each point along the flow path of said circulating culture medium are in the ratio 1:0.1 to 1: 0.2. In an embodiment, these coils are wound around a 'wire cage'(2) as illustrated in Figure 2, which would provide strips of shadow or less light intensity zone at regular intervals to result in alternating light and darkness time periods on each point along the flow path. Vertical strips of black-paper at the opposite face of the cage after the tube may be provided to further ensure reduction in light intensity in that zone. In another preferred embodiment of photo bio-reactor said means of providing periods of light and darkness comprises an electronic flashing device. In order to get best results, there is preferably a cycle comprising alternately continuous darkness time period of 8 hours after each period of 16 hours of said alternating light and darkness time periods. The bio reactor has a de-gasser chamber(4) having hydraulic connection with said free end of the first coaxial coil for removing unwanted gases from said culture medium. Optionally, a stirrer(S) is provided in said de-gasser chamber for keeping the bio-mass in suspension in said culture medium. In a preferred embodiment, the stirrer is a magnetic stirrer or a small air-lift reactor for suspending the culture. The de-gasser chamber has hydraulic connection with a heat exchanger(6) for controlling temperature of said culture medium preferably between 25° C and 36° C. The heat exchanger may comprise a water bath for heating and/ or a chilling unit for cooling. The water bath may comprise copper coils for flow of said culture medium, fitted inside a container for water circulation. The bio reactor has a rneans(7) for causing flow of said culture medium in said coils without said means coming into direct contact with said medium. In a preferred embodiment this means is a perislatic pump(7), which acts on the outer surface of the tube to cause pumping of the culture medium without coming in contact with the medium. A gas injection means(8) is connected to said de-gasser chamber of the bio reactor on one end and said free end of last coil on the other end. In a prferred embodiment the gas injection means may be a Y-shaped junction(8) having two inlet arms and one outlet arm with said outlet arm connected to said free end of last coil and said two inlet arms connected to a CO2 source and an air source respectively.The flow of the air plus carbon-dioxide and the pump together are kept such that the relative superficial velocity of the gas with respect to the liquid does not exceed the value 0.085 m/s. We can obtain such value by taking air flow rate to be flow rate to be 0.085 m/s. In a preferred embodiment flow rate of said circulating culture medium is from .085 m/s to 0.10 m/s and said gas flow rate is between 0.170 m/s to 0.200 m/s. A preferred method of cultivating and harvesting a bio-mass in the photo bio-reactor of present invention comprises the steps of: (a) circulating a culture medium containing a micro algae in said reactor at a predetermined flow rate; (b) providing alternately period of light and darkness for predetermined time periods on each point along the flow path of said circulating culture medium; (c) removing unwanted gases from said circulating culture medium; (d) controlling temperature of said culture medium between 25° and 36° C; (e) optionally, stirring said circulating culture medium to keep said micro algae in suspension; (f) injecting CO2 and air into said circulating culture medium to ensure a predetermined gas flow rate; (g) providing continuous darkness for a predetermined time period on each point along the flow path of said circulating a culture medium; and (h) harvesting cultivated micro algae from said circulating culture medium. The micro algae used is Botryococcus braunii. The method may also be adapted for cultivating and harvesting spirulina or any other algae. In the preferred embodiment, the modified Chu-13 medium is used to culture B. braunii. This medium has the following composition (Kgnr3) at four-fold normal strength: KN03 (0.2) Copper (0.02ppm) K2HPO4 (0.04) Cobalt (0.02ppm) MgS04.7H2O (0.1) Molybdenum (0.02ppm) CaCl2.6H2O (0.08) Manganese (O.Sppm) Ferric Citrate (0.01) Boron (O.Sppm) Citric Acid (0.1) The production of hydrocarbons in B. braunii appears to be growth associated, irrespective of the specific culture conditions and the nutrients used. The production of hydrocarbon is energetically demanding and thus it leads to slow growth rate of algae and so is not dominated by the amount of nutrients present. The color of algal colonies is dependent on the carotenoid-to-chlorophyll ratio, which is affected by the intensity of light. Carbohydrates concentration, cellular nitrogen, and phosphorus content of B. brauni are decreased by extended exposure to a light intensity. Colony size increase with increased light intensity initially when the cell concentration is low and sufficient light for photosynthesis was available. As the cell concentration increase, the average light intensity within the photobioreactor decreased because of mutual shading, and thus the production rates of extracellular polysaccharides and hydrocarbons decrease with decreasing average light intensity. The equilibrium colony size is determined by a dynamic balance between the mechanical strength of colonies and the hydrodynamics stress due to turbulence in the reactors. The pH of the culture medium is generally adjusted to between 7.4 and 7.6 before inoculation. A regular increase in pH is observed during active growth followed by a slight decline later. The increase in pH is partly due to the consumption of dissolved CO2 for photosynthesis. Similar changes in pH are observed in CO2 enriched culture during exponential growth. Potentially domestic sewage that has been pretreated by activated sludge treatment can be used as a medium for hydrocarbon production by B. braunii. Sewage can reduce the cost of producing the hydrocarbons. Secondary stage-treated sewage (STS) has been characterized, and found to contain a large amount of nitrogen (as nitrate) and phosphorus (as phosphates). Botryococcus cannot grow on industrial wastewater containing a high concentration of inorganic ions. Potentially, the productivity of continuous algal culture can be improved by optimizing the dilution rate. The optimal dilution rate is expected to depend on the strength of wastewater and the intensity of illumination. The pH is adjusted to 7.5 before sterilization. Optimum temperature for growth is 25-30° C. Reviews of the different techniques available (flocculation, filtration, centnfugation and air flotation) have concluded that centnfugation is possibly the most reliable technique and only slightly more expensive than other techniques. Here we have assumed that the goal of microalgal biotechnology efforts to recover a high value product from the microalgal biomass. Thus, the high value product needs to be separated from the biomass. Depending on the process, the microalgal cells may need to be physically disrupted. Both ball mills and high pressure homogenisers have been used successfully to disrupt microalgal cells to enhance recovery. Depending on the product to be recovered, in the process it might entail reducing the water content of the microalgal biomass. Absence of water in the biomass enhances the recovery of lipid soluble components . Microalgal mass can be dehydrated in spray dryers, drum dryers, freeze dryers and sun dryers. In the case of Heat sensitive compounds commercial producers have developed technologies that limit exposure to conditions known to cause degradation. In some cases the biomass may not need to be dehydrated, and the extraction and fractionation can be carried out on the wet biomass. Further downstream processing may be needed to isolate the active compound depending on the intended final product. Use of solvents and enzymes might help with cellular disruption and product recovery but care must be taken regarding what aids are used if the product is intended for human consumption. NIES-N-836. B. braunii, sourced from Japan (NIES culture collection centre) was obtained from Central Food Technological Research Institute, Mysore, India and was used for evaluation of the performace of the reactor and other studies. Example 1 In order to inroduce flash light effect, a wire strip is intermittently interposed between light source and tube. In an embodiment, for every tubular length of 2.3 cm the wire strip has a thickness of 0.3 cm. Thus Flash-Lighi effective ratio = time in darkness / time in light = 0.3/2.0 =1: 0.15 Example 2 The Biomass estimation is carried out by the following steps: 1. 25ml. medium is harvested. 2. Take eppendorf and pre-weigh it. 3. Transfer the pellet into eppendorf and lyophilize. 4. Weigh the eppendorf again. The difference hi weights is the weight of the biomass. Hydrocarbon estimation by gravimetric method: 1. Sonicate known quantity of biomass in n-hexane for 30 min. 2. Centrifuge and take the supernatant in pre-weighed vials and evaporate the solvent under nitrogen to complete dryness. 3. Repeat the extraction 2 more times, pool the solvents and evaporate to complete dryness with nitrogen. 4. The weight of hydrocarbons is calculated by the difference in the weight of vial. Determination of growth of B. braunii: The doubling time for biomass growth rate in the exponential phase is found to be nearly 8-9 days at 27°C and 14-15 days at 31°C as shown in the Figure 5 and 3 respectively. The hydrocarbon accumulation was found to be growth associated and comprised 50-55% of the cell mass as shown in Figures 4 and 6. I CLAIM: 1. A photo bio-reactor for cultivating and harvesting a bio-mass suitable for producing hydrocarbon comprising: (i) a helical tubular system having a plurality of substantially coaxial helical transparent tubular coils(l), which could be easily autoclaved, for flow of a culture medium containing micro algae to be cultivated, each coil being hydraulically connected to its adjacent coaxial coil, said coils having annular spaces interposed between the adjacent coils and a space enclosed by the inner diameter of innermost coil, the first and the last coil each having a free end; (ii) a means (2) of providing periods of light and darkness on each point alternately for predetermined time periods on the inner and outer surfaces of each of said coil; (iii) a de-gasser chamber (4) having hydraulic connection with said free end of first coil (1) for removing unwanted gases from said culture medium; (iv) optionally, a stirrer (5) or 'perfusion air-lift reactor' (5) provided in said de-gasser chamber(4) for keeping the bio-mass in suspension in said culture medium; (v) said de-gasser chamber (4) having hydraulic connection with a heat exchanger (6) for controlling temperature of said culture medium; (vi) a means (7) for causing flow of said culture medium in said coils without said means coming into direct contact with said medium; and (vii) a gas injection means (8) connected to said de-gasser chamber (6) on one end and said free end of last coil on the other end. 2. A photo bio-reactor as claimed in claim 1, wherein said transparent autoclavable tubular coils comprise silicone polymer material. 3. A photo bio-reactor as claimed in claim 1, wherein said means of providing light comprises incandescent lighting device selected from a plurality of tube-lights, light emitting diodes and optical fibers or a combination thereof. 4. A photo bio-reactor as claimed in claim 1, wherein said means of providing period of darkness comprises a plurality of opaque strips or wires of predetermined width or diameter. 5. A photo bio-reactor as claimed in claim 1, wherein said means of providing periods of light and darkness comprises an electronic flashing device. 6. A photo bio-reactor as claimed in claim 1, wherein said stirrer is a magnetic stirrer or a 'perfusion air-lift reactor'. 7. A photo bio-reactor as claimed in claim 1, wherein said heat exchanger comprises a water bath for heating and/ or a chilling unit for cooling. 8. A photo bio-reactor as claimed in claim 7, wherein said water bath comprises copper coils for flow of said, culture medium, fitted inside a container for water circulation. 9. A photo bio-reactor as claimed in claim 1, wherein means for causing flow of said culture medium comprises a peristaltic pump or any pump maintaining sterile condition. 10. A photo bio-reactor as claimed in claim 1, wherein gas injection means comprises a Y-shaped junction having two inlet arms and one outlet arm with said outlet arm connected to said free end of last coil and said two inlet arms connected to a CO2 source and an air source respectively. 11. A method of cultivating and harvesting a bio-mass in a photo bio-reactor as claimed in claim 1, comprising the steps of: (a) circulating a culture medium containing a micro algae in said reactor at a predetermined flow rate; (b) providing alternately period of light and darkness for predetermined time periods on each point along the flow path of said circulating culture medium; (c) removing unwanted gases from said circulating culture medium; (d) controlling temperature-of said culture medium between 25° and 36° C; (e) optionally, stirring said circulating culture medium to keep said micro algae in suspension; (f) injecting CO2 and air into said circulating culture medium to ensure a predetermined gas flow rate; (g) providing continuous darkness for a predetermined time period on each point along the flow path of said circulating a culture medium; and (h) harvesting cultivated micro algae from said circulating culture medium. 12. A method as claimed in claim 11, wherein said micro algae is Botryococcus braunli 13. A method as claimed in claim 12, wherein said culture medium is a modified Chu-13 medium. 14. A method as claimed in claim 11, wherein said alternating light and darkness time periods on each point along the flow path of said circulating culture medium are in the ratio 1:0.1 to 1:0.2. 15. A method as claimed in claim 11, wherein flow rate of said circulating culture medium is from .085 m/s to 0.10 m/s. 16. A method as claimed in claim 11, wherein said gas flow rate is between 0.170 m/s to 0.200 m/s. 17. A method as claimed in claim 11, wherein said continuous darkness time period is 8 hours after each period of 16 hours comprising said alternating light and darkness time periods, 18. A method as claimed in claim 11 as and when used for cultivating spirulina.

Full Text

Field of Invention
This invention relates to a PhotoBioreactor for cultivation of Botryococcus braunii and a
method for efficiently growing the microalgae. More particularly, the invention relates to
a PhotoBioreactor and method for cutivation of biomass for producing bio-diesel. The
bioreactor and the method can be adapted to production of other microalgae including
spirulina.
Botryococcus braunii, is a highly rich renewable source of hydrocarbons. The high cost of
known microalgal culture systems relates to the need for light and the relatively slow
growth rate of the algae. The photobioreactors must be designed keeping in mind that
light is needed continuously for microalgal cultures. Since the intensity of light decreases
rapidly with the depth of the culture, the geometry of the reactor is equally important.
Important concern is to reduce the costs of these systems further to make them
economically competitive.
Bioreactor System design depends on organism property, media property and system
kinetics. The property of the organism is important because we need the organism to
grow in the desired fashion so that the acclaimed metabolic route is followed to yield us
the preponderance of desired product. Factors such as Oxygen / Carbon Dioxide
dependency play crucial role, hence the importance of the size of the bubble and the time
it spends in the liquid column. We also need to take care of the hydrodynamic shear since
the growth may decrease sharply after increase of gas flow rate beyond certain value due
to cell damage. Cell damage is dependent on the strain used, the bubble size based on the
nozzle because smaller nozzle, which produce smaller bubbles, are more detrimental. But
there is advantage of having smaller nozzle as it gives in more diffusion of the gas in the
medium, and hence we need to make an optimum choice. Thus there is a need of proper
sparger. In general superficial air velocity of 0.085 m/s can be considered the upper limit
beyond which organism without cell wall can undergo damage. In case of scale up, when
more quantity of gas is required, we must assure either increasing the number of nozzles
or increasing the diameter does not exceed this velocity.
Algae use light as an energy source and obtain all the carbon they need from inorganic
sources (CO2) and are thus photoautotroph. Micro algal biotechnology has the potential to
produce a vast array of products including foodstuffs, industrial chemicals and
compounds with therapeutic applications, bioremediation solutions and hydrocarbons.
Background Art
Oak Ridge National Laboratory and Ohio University have been demonstrating the and
biomass production in photobioreactors using sunlight. Large solar collectors on the roof
track the sun, collect sunlight, and distribute it through large optical fibers to the
bioreactor's growth chamber. The fibers function as distributed light sources to illuminate
cyanobacteria (algae). Each growth chamber consists of a series of illumination sheets
containing the optical fibers and moist cloth-like membranes on which the algae grow. By
stacking the membranes vertically and better distributing the light, more algae can be
produced via photosynthesis in a smaller area.Ohio University photobioreactors use
sunlight to sequester carbon from coal-fired power plants as they produce biomass.A
drawback of this system is that in horizontal cultivator systems, light penetrates the
suspension only to 5 cm, leaving most of the algae in darkness. The top layer of algae
requires only about 1/10th the intensity of full sunlight to maximize growth, so the
remaining sunlight is wasted.
James C. Ogbonna and Hideo Tanaka have developed a prototype photobioreactor
consisting of four units built with 0.5-cm-thick transparent Pyrex glass for the cultivation
of C. pyrenoidosa. Each unit was equipped with a centrally fixed glass tube into which
the light source was inserted. Transparent glass tubes were used as housings for the
lamps, so the reactor was illuminated by simply inserting the lamps into the glass tubes
(no mechanical fixing). Any light source could be used. Either 4-W fluorescent or
halogen lamps with controllable light intensity were used as the illuminating system.
Because the lamps are not mechanically fixed and can easily be replaced, the same reactor
can be used for efficient cultivation of various cells by using a light source with
controllable light intensity or by simply replacing the light source with one that gives the
desired light intensity. For mixing, an impeller modified in shape is used so that it did not
touch the glass housing unit during rotation.
United States Patent 5,614,378 (Yang , et al, March 25, 1997) discloses a photo bio
reactor comprising a hollow, cylindrical irradiation chamber, wherein said chamber
comprises a top sealed to a cylindrical side wall; a bottom sealed to said cylindrical side
wall; said top, bottom and cylindrical side wall together enclosing a cylindrical space; a
first cylindrical light irradiator disposed in said cylindrical space and attached only to said
top; and a second cylindrical light irradiator disposed in said cylindrical space and
attached only to said bottom; wherein all cylindrical light irradiators and said cylindrical
side wall are coaxial; the distance between said cylindrical side wall and cylindrical light
irradiator closest to said side wall is within 1 mm to 20 cm, and the distance between
each adjacent cylindrical light irradiator is within 1 mm to 20 cm, for a time sufficient to
produce said biologically-active compound, while irradiating said cells with said first
light cylindrical irradiator and said second light cylindrical irradiator. This photo
bioreactor may also be used in a method to fix carbon dioxide, to produce, e.g., fuels
and/or chemical feed stocks. In this application, the cultured cells are suitably, e.g.,
Botryococcus braunii.
United States Patent 4,952,511 (Radmer , August 28, 1990) teaches a photo bio reactor
which comprising a tank for containing a liquid microbial culture; a high-intensity light
source whose light is substantially entirely directed into a light compartment; said light
compartment having at least one transparent wall extending into said tank; and said light
compartment containing a tube of internally reflective prismatic sheet, said tube
extending substantially from said light source to an end wall of said light compartment
opposite said light source and said tube having transverse dimensions sufficient to
substantially surround said light source, said tube further including a mirror at the end
thereof opposite said light source oriented to reflect light back into said tube, wherein the
light source, the tube and the mirror are arranged, so as to distribute light from said highintensity
light source substantially uniformly across the interior surface of the transparent
wall of said light compartment.
United States Patent 5,137,828 (Robinson , et al. August 11, 1992) teaches an apparatus
comprising an upstanding substantially cylindrical support structure; a substantially
transparent tube supported by the support structure and wound helically on the outside
thereof so that, in use, the exterior of the wound tube is exposed to natural light, said tube
containing at least living plant matter; a header tank at the top of the support structure, the
upper end of the transparent tube being connected to the header tank; a pipe extending
from the header tank to the bottom of the support structure, said pipe being connected to
the lower end of the transparent tube; means for causing a synthesis mixture to flow under
turbulent conditions through the tube, the header tank and the pipe; and means for
withdrawing a biomass synthesis product from at least one of the header tank and the
wound tube.
United States Patent 4,724,214 (Mori February 9, 1988) discloses an apparatus for
photosynthesis comprising bath means containing a photosynthetic reaction bath, a
plurality of tubular photoradiators arranged upright in said bath means in parallel array,
upper support means and lower support means in said bath means for supporting the
upper and lower end portions respectively of said tubular photoradiators, said tubular
photoradiators being spaced from one another so as to define a plurality of upright
passages between said tubular photoradiators, said upper support means closing off the
upper ends of said upright passages, said bath means having a lower chamber underlying
said lower support means, said lower support means having a flow-through portion which
provides communication between said chamber and a first plurality of upright passages
and a stopped up portion which blocks communication between said chamber and a
second plurality of upright passages, conduit means leading to said chamber for supplying
CO2 -containing air, said flow-through portion and said stopped up portion of said lower
support means being constructed and arranged such that said air passes from said
chamber through said flow-through portion into said first plurality of upright passages,
said air passing upwardly in said first plurality of upright passages and subsequently
being directed generally laterally by said upper support means such that the air then
passes downwardly in said second plurality of upright passages to subsequently again be
directed generally laterally by said stopped up portion of said lower support means to
once again pass upwardly in said first plurality of upright passages, whereby the air
circulates in said bath means between said tubular photoradiators.
United States Patent 4,676,956 (Mori June 30, 1987) teaches an apparatus for photo
synthesis comprising a reaction bath means for causing a photosynthetic reaction therein,
said reaction bath means comprising an inner transparent wall and an outer transparent
wall surrounding and spaced from said inner transparent wall to define an annular space
between the inner and the outer transparent walls, the inner and outer transparent walls
being generally vertically disposed, and a light source positioned radially inwardly of the
inner wall; a plurality of narrow tubular photoradiators arranged upright in said annular
space parallel to each other, each of said photoradiators being constructed to radiate light
which propagates therethrough; and a disc rotatable in a horizontal plane below the
reaction bath means and disposed perpendicular to the photoradiators to eject jets of
carbon dioxide-containing air into the annular space.
Japanese Patent JP7023767 provides a culture tank opened at one end provided with a
fixing plate having plural holes to close the open end of the culture tank. Plural
protection tubes made of a transparent material and each having an insertion opening at
one end and closed at the other end are fixed to the fixing plate parallel to each other by
bonding the circumference of each hole to the outer circumference of the insertion
opening. The fixed tubes are put into the culture tank. A rod light-source is removably
inserted into each protection tube and a lid is applied to the fixing plate at the side
opposite to the side holding the protection tubes. The circumference of the opening of the
culture tank 10 is detachably fixed to the circumference of the fixing plate in liquid-tight
state with an engaging means to provide this photo- bioreactor.
Japanese Patent JP9009953 teaches a method to obtain a new Botryococcus braunii B
race strain producing hydrocarbons mainly consisting of 30-33C hydrocarbons and
containing above a specific weight ratio of a 30C hydrocarbon to the total of
hydrocarbons. Planktons on the surface of Ippeki lake (Shizuoka prefecture) are collected
by using a Kitahara type plankton net with 25u. m mesh. The prepared specimen is
observed by a microscope and a colony of an alge of the genus Botryococcus is collected.
The colony is cultured in a test tube, a single colony of the alga of the genus
Botryococcus is raked by a platinum wire while observing characteristic properties of the
alga of the genus Botryococcus in a colony state, etc., by using a stereoscopic microscope
and cultured in a float plate medium to give a new Botryococcus braunii B race strain
which produces hydrocarbons consisting mainly of 30C to 33C hydrocarbons and
containing >=5wt,% 30C hydrocarbon based on the total of hydrocarbons and is
Botryococcus braunii SI-1 strain.
Japanese Patent JP9234055 recites a method for efficiently culturing the strain of fine
algae belonging to the genus Botryococcus braunii A race capable of producing a 33C
hydrocarbon. A hydrocarbon produced by the alga of this strain contains a 33C
hydrocarbon. The new strain of the fine alga belonging to the genus Botryococcus braunii
A race is cultured under intermittently irradiating the strain with an artificial light
preferably once daily for 5-15 hours.
Japanese Patent JP9173050 method for efficiently culturing a microalgae belonging to
green algae, which has ability to fix CO2 by light energy and converts it into useful
substances such as fuel comprises culturing microalgae (e.g. Botryococcus braunii
CCAP807/1, etc.) belonging to such as Botryococcus, Chlorella, or Haematococcus,
which belongs to green algae, while adding intermittently a disinfectant such as
hypochlorous acid, hypochlorite, hydrogen peroxide and ozone to the culture medium
intermittently each in a quantity of 0.01-200ppm so as to attain an effective quantity of
the disinfectant in an open system under conditions of light illuminance and aeration of
0.05-5wm air containing CO2 in concentration of 0.03-30% at culturing temperature of
10-4°C for about 10 days.
Accordingly, various types of Biorectors known in the art are described along with draw
backs in the following paragraphs.
A common CSTR type reactor, which is externally illuminated by light source. This has a
poor surface to volume value and since the illumination is from outside, a major part of
light energy is wasted and inefficiently utilized.
A common lab scale reactor provides high light supply capacity and can be illuminated
by both artificial and solar light. However, this has a poor surface to volume value and so
a large number of light tubes would be required and thus would be energy consuming, a
factor very detrimental for scale up.
A Flat Plate reactor derives the laminar concept from plants. If light energy has to be
available continuously to the cells, a lamination of photobioreactor directed to the light
source seems to be the best solution. Apart from the high surface/volume value offered in
case of tubular reactors, plate-type reactors have some advantages with respect to
compactness. The advantages of a flat plate photobioreactor include easy introduction of
turbulence, easy approachability of inner walls, providing easy control of wall growth and
fouling and they may be tilted towards sun, ensuring higher absorption of incident energy.
However, there is a major demerit of problems faced when attempting to scale-up since a
corresponding increase in width would lead to a reduction of light intensity in the inner
section of the reactor.
In a typical airlift reactor, mass transfer is high and short liquid circulation time can be
obtained. Further there is insignificant hydrodynamic stress. The riser can comprise of the
dark zone and the down comer as photic zone. Airlift operation uniformly suspends
microplantlets and improves exposure to light. Also there is continuous addition of
nutrient medium and high cell density would be obtained in matter of time such that
biomass is retained within vessel. Possibly modification include introducing alternating
dark and transparent section in the inner column to take into account of organism specific
flashing light effect. However, if the light source is from outside then there would be
major loss in the energy.
One of the most promising closed tubular photobioreactors design is the helical reactor.
Tubular systems are generally arranged in a Horizontal serpentine form and made of glass
or plastic tubes. Recirculation of culture suspension can be obtained by airlift technology
or by means of pump. Floating or submerging the tubes on or in a pool of water
controlled temperature, oxygen degassing being guaranteed by flexible tube elements.
Biocoil is an arrangement of coiled polyethylene tubes of about 30-60 mm diameters
around an open circular framework.
Helical tubular photobioreactor is advantageous because it allows a larger ratio of surface
area to culture volume to receive illumination effectively, thereby reducing the selfshading
phenomenon. Thus there is improved light transfer since the tube diameter has
short light path to reduce light attenuation through culture suspension However this
reactor has a drawback that upscaling involves large area for a given biomass production.
Objects of Present Invention
The principle object of the present invention is to propose a photo bioreactor for
efficiently growing the microalgae Botryococcus braunii with an enhanced growth rate
than obtained by bioreactors known in the art.
Another object of the present invention is to propose a method efficiently growing the
microalgae Botryococctts braunii with an enhanced growth rate than obtained by the
methods known in the art.
Yet another object of the present invention is to propose a bioreactor and method which
is simple and economical to implement.
Other objects and advantages of the present invention will be clear from the description,
examples, claims and drawings which follow.
Statement of Invention:
According to one aspect of the invention there is provided a photo bio-reactor for
cultivating and harvesting a bio-mass suitable for producing bio-diesel comprising: (i) a
helical tubular system having at least two substantially coaxial helical transparent
autoclavable tubular coils for flow of a culture medium containing micro algae to be
cultivated, said coils being at least a first coil and at least a last coil, each coil being
hydraulically connected to its adjacent coaxial coil, said coils having annular spaces
interposed between the adjacent coils and a space enclosed by the inner diameter of
innermost coil, the first and the last coil each having a free end; (ii) a means of providing
periods of light and darkness on each point alternately for predetermined time periods on
the inner and outer surfaces of each of said coil;(iv) a de-gasser chamber having
hydraulic connection with said free end of first coil for removing unwanted gases from
said culture medium; (v) optionally, a stirrer provided in said de-gasser chamber for
keeping the bio-mass in suspension in said culture medium; (vi) said de-gasser chamber
having hydraulic connection with a heat exchanger for controlling temperature of said
culture medium; (vii) a means for causing flow of said culture medium in said coils
without said means coming into direct contact with said medium; and (viii) a gas
injection means connected to said de-gasser chamber on one end and said free end of last
coil on the other end.
According to another aspect of the invention there is provided a method of cultivating
and harvesting a bio-mass in a photo bio-reactor as claimed in claim 1, comprising the
steps of: (a) circulating a culture medium containing a micro algae in said reactor at a
predetermined flow rate; (b) providing alternately period of light and darkness for
predetermined time periods on each point along the flow path of said circulating culture
medium; (c) removing unwanted gases from said circulating culture medium; (d)
controlling temperature of said culture medium between 25° and 36° C; (e)
optionally, stirring said circulating culture medium to keep said micro algae in
suspension; (f) injecting CO2 and air into said circulating culture medium to ensure a
predetermined gas flow rate; (g) providing continuous darkness for a predetermined time
period on each point along the flow path of said circulating a culture medium; and (h)
harvesting cultivated micro algae from said circulating culture medium.
Brief Description of Accompanying Drawings
Figure 1. shows the photobioreactor.
Figure 2. shows the cage around which the helical coil is wound.
Figure 3. shows the growth profile of B. braunii at 31 °C
Figure 4. shows the hydrocarbon content profile of of B. braunii at 31 °C
Figure 5. shows the growth profile of B. braunii at 27 °C
Figure 6. shows the hydrocarbon content profile of of B. braunii at 27 °C
Detailed Description
The ability of photoautotrophic microbes to make use of solar energy for metabolism is
dependent upon the effective surface area of the rays to which it is subjected, which
reduces with increase in population. As opposed to heterotrophic microorganisms where
mixing solves the distribution of the organic molecules as energy carriers by mixing, the
supply of photons is based on the surface area. Light gradient would always tend to occur
due to mutual shading of the cells and light absorption. The light intensity in a
photobioreactor decreases exponentially with the depth. Since the intensity of light
decreases rapidly with the depth of the culture, the geometry of the reactor is equally
important.
High alteration between subjecting to light regime and dark regime in the order of
microseconds to up to a second results in enhancement of photosynthetic efficiency. It has
been observed that turbulence in an optically dense culture increases the efficiency of
light utilization by photosynthesis. This effect is denoted as a flashing light effect. This
effect is due to the fact that photosynthesis does not cease at the instant when light is
removed but continues until the energy absorbed in the prior light period has been used
and chemically stored. Short cycle time flashing light effect could be a result of fast effect
of electron acceptors associated with the photo-system II followed by their oxidation in
the dark period. In turbulence, individual cells are subjected to a pattern of light and dark
periods. The flashing light effect could thus increase photo-accepting capacity. The
subjection of Light & Dark regime should not be in the order of seconds, as it would then
lead to reduction in photosynthetic activity resulting in reduced biomass yield. But the
exact order of the Light/Dark value depends on the organism of choice and the product
required. However, it is evident that this Light/Dark cycle will determine the efficiency
and productivity that we desire for a given compound. Algal culture is in light demand
through antenna pigments in the cell. Antennas that are damaged need a recovery time.
Helical tubular bioreactor facilitates temperature control and restricts contaminants
because it is a closed bioreactor. There is better CO: transfer from the gas stream to the
liquid culture medium due to the extensive CO2 absorbing pathway. Possibly, a
modification may include introducing alternating dark and transparent section in the inner
column to take into account of organism specific flashing light effect. Its disadvantages
include requirement of a large land area for a given volume. Another aspect is that the
system is suitable only for disperse culture suspension as pump action disperses cell
clumps.
Some factors that influence the light requirement of an algae culture are:
/. Type of algae culture and optimum wavelength: The Light requirement of algae
depends on the major pigment present on the algae. Different pigments absorb light in
different range of wavelengths; chlorophyll a in the range of 400-450 nm (between Violet
and Blue) and around 680nm(Red), p-carotene 400-500 nm (Violet to Green), chlorophyll
b (400-500nm). Further we also need to remember that energy delivered is inversely
proportional to the wavelength, but the penetration is directly proportional to the
wavelength. In Green algae Chlorophill a, Chlorophill b and (3-carotene are light
harvesting pigments which have their absorption wavelength maxima in the range
400nm-500nm and 620-680nm.
2. Type of Light source: Some of the efficient light sources from the electric consumption
and wavelength requirement point of view are Light Emitted diodes (LEDs), Fluorescent
lights, and incandescent/halogen lamps. Fluorescent lamps are used most frequently for
the cultivation of phototrophic organisms. The emission wavelength emitted from the
mercury vapor can be converted to continuous radiation by modifying the composition of
the fluorescent material, which allows for an optimum spectrum of photosynthesis. LEDs
are one of the most efficient one in converting electricity to light with desired
wavelength. However, if broader wavelength is required then combination of LEDs has to
be used. We also need to keep into account the increase in wavelength due to absorption
of rays as Heat energy.
3. Intensity of Light source: The light intensity at which the cell growth begins is called
the compensation intensity (Ic) and the light intensity after which no further increase in
growth takes place with increased light intensity is called the saturation intensity (Is).
After a certain more increased value of light intensity, decrease in specific growth rate
starts to takes place. This phenomenon is called photoinhibition and the intensity is
denoted (Id). Further, the values of Ic, Is and Id is strain and temperature dependent. The
specific growth rate of algae increases linearly with light intensity up to the saturation
light intensity, thereafter-light inhibition is observed. Generally, the Is increases as the
temperature is increased resulting in increased specific growth rate.
In general, the helical system bioreactors prove to be better than the stirred system. This
can be attributed to large dark volume characterized by cylindrical reactors. This dark
volume can be taken care by inserting transparent pipes into the cylinder from the top
through holes in the lid, holding fluorescent tubes, such that it can easily be removed
during sterilization. T-shaped multifunctional stirrer is used to agitate the suspension and
to supply sterile air.
The denser is the culture of micro algae, the more problematic is the light penetration,
and extremely limited. This restricts the commercial production to just flat plate
photobioreactor and narrow bore tubular reactor. In spite of the efficient performance of
thin channel flat plate types of photobioreactors, there is difficulty in scaling it up for
production of significant quantities of product. This further limits our choice to tubular
photobioreactor. The major disadvantage of tubular reactors is that for the same amount
of volume, the area required is much more in comparison to other reactors. Other
possibilities comprise of bubble column and airlift reactors that are more compact than
tubular devices and can be deployed if a certain loss of productivity is acceptable.
From Commercial point of view, a PBR must have high productivity, large volume, low
maintenance and building expenses, and flexibility and ease to control culture parameters.
Use of Immobilized Algal Cells
Immobilized cell culture offers important advantages over free suspension in particular
when the cells are slow growing. Extra-cellular products can be recovered continuously
with ease. Since micro algae are shear sensitive, immobilization can protect cells against
hydrodynamic shear forces. Immobilization by Calcium Alginate beads results in cells
with enhanced chlorophyll content in attempt to capture more of the available light. Gelentrapped
cells are thus protected from photoinhibition, a condition in which intense
irradiance actually causes a loss in photosynthetic performance. However, Alginate gelimmobilized
cells have a lower growth rates and lower biomass production relative to
free controls, possibly because immobilization can reduce availability of substrate to the
cells. It is to be noted that Immobilized cells retain the ability to produce hydrocarbons,
whose structure and relative abundance are not affected by immobilization. PUF
(Polyurethane Foams) support matrices have broad range of porosity and mechanical
strength. However, the exposure to light to the cells drops down noticeably and so does
the growth. Cotton gauze - immobilized B. braunii cells show higher levels of
hydrocarbon production, biomass growth, and photosynthetic activity when compared
with cells immobilized in PUF. Despite advantages, the practicability of immobilized
algal culture remains questionable unless the cells can be cultured in long-duration
continuous culture and the hydrocarbons can be extracted continuously, say by doing
some protein engineering for post-translational modification in the corresponding DNA
sequence, or by selectively subjecting the beads to extracting solvent such that the
hydrocarbon is extracted and the cell remains as it is inside the beads.
B. braunii has a disperse culture growth and growth into clump-form is not an advantage
to the organism, rather causes reduction in the supply of oxygen to the inner cells. Hence
application of Tubular coiled reactor is advantageously is the best for the purpose. High
surface to volume value is desired for more or less equal distribution of light intensity.
Hence application of Tubular coiled reactor serves best for the purpose.
hi a preferred embodiment, to introduce proper Flashing light effect for the organism B.
braunii dark strips of appropriate width are introduced at regular intervals, such that the
order is not more than a second. For maximum utilization of energy, light is provided
from inside and not from outside, such as inside the coiled helix in the Tubular coiled
reactor. To ensure better distribution of light, straight tube-lights may be preferred over
bent 'U' shaped tube-lights. Light of appropriate wavelength must be used which is
optimum for B. braunii. Typically in Green algae Chlorophill a, Chlorophill b and 6-
carotene are light harvesting pigments which have their absorption wavelength maxima in
the range 400nm-500nm and 620-680nm. Either single fluorescent light can be deployed
covering the entire wavelength of 400-700nm, or 2 LEDs can be made use of, one with
the emission bandwidth of 400-500nm and another with 600-700 nm as LEDs have a
narrow bandwidth. The choice would be governed by comparative economics.Light
intensity is kept to be around saturation intensity, as an increase further would lead to
decrease in growth rate and wastage of energy. Use of Solar-Light and optical fibre can be
deployed since in a Tropical country such as India there is abundant supply of solar
energy.
Care is taken to ensure appropriate and more-or-less uniform temperature as the
saturation intensity changes with change hi temperature, and would thus lead to errors in
observation. In general superficial air velocity of 0.085 m/s can be considered the upper
limit beyond which organism without cell wall can undergo damage. Since each cell of B.
braunii has its own cell wall, we can operate at values above this numerical figure, but at
the same time the value should not be very high as micro algae are known to be shear
sensitive.
The Carbon-Dioxide percentage of 5% can be considered to be optimum for microalgae
growth though the exact optimum value would be dependent on other factors such as the
strain & temperature.
Tubular Helical PBR takes into account of most of the above considerations. The only
demerit is the large land area required for scale up as for a given volume the coiled tube
would be very long
. The present invention nullifies this effect and thereby reduces the problem of large land
area.
In an embodiment, a peristaltic pump is provided it is not harmful for the shear-sensitive
organism such as the B. Braunii. Usage of pump also reduces the chances of reverse flow.
Additionally, the pump action also disperses cell clumps and thereby facilitates more of
absorption of nutrients and light by individual cells. Care should be taken that pressure of
the medium being pumped does not exceed the osmotolerance pressure which is 1
atmosphere (guage).
The present 'Flash Light Super Helical Photo Bio Reactor' takes care of the scalability
issue of traditional helical photobioreactor and also introduces increase in the
photosynthetic activity of the microalgae by Flash-Light effect.
A preferred embodiment of the bio-rector comprises a helical tubular system having at
least two substantially coaxial helical transparent autoclavable tubular coils(l) for flow of
a culture medium containing micro algae to be cultivated, each coil being hydraulically
connected to its adjacent coaxial coil, said coils having annular spaces interposed
between the adjacent coils and a space enclosed by the inner diameter of innermost coil,
the first and the last coil each having a free end. The number of coaxial coils may be 2 or
3 or more. The end of each coil is hydraulically connected to the starting point of
adjascent coil.
The primary requirements of the tube forming superhelical structure is that it should be
transparent and autoclavable. Further, it should be non-fragile and economical. One
possibility was that of Glass. Though glass satisfies the first two criteria extremely well, it
is highly delicate and mishandling or accidental touch can destroy the entire setup.
Further, the cost of fabrication using Glass for the above scheme turns out to be
extremely high. More importantly, the brittle and fragile nature of glass makes it
incapable to tolerate high guage pressure over an extended period. Lastly, there is
constraint on the fabrication in limiting the gap distance between any two adjacent rings
to be not less than a centimeter, which reduces the compactness and thereby the
scalability.
In a preferred embodiment, pipe material used which is resistant to heat and is
autoclavable is transparent type Silicone Tube. Though the transparency of Silicone is not
as good as that of a Glass, silicone is flexible, non-fragile, autoclavable and costs almost
half of what it costs for fabrication using Glass. The photostage of present invention
comprises said transparent autoclavable tubular coils made from silicon polymer material.
The bio reactor has a means(2,3) of providing Flash-Light effect i.e. periods of light and
darkness on each point alternately for predetermined time periods on the inner and outer
surfaces of each of said coil. In a preferred embodiment means(3) for providing periods
of light is a plurality of tubelights uniformally placed in the annular space between two
adj ascent coils and the space enclosed by inner diameter of the innermost coil. In another
embodiment, a plurality of light emitting diodes is used for this purpose. An optic fiber
coil may be used to provide solar illumination in another embodiment. In another
embodiment, a combination of these means are used. In a preferred photo bio-reactor
means(2) of providing period of darkness comprises a plurality of opaque strips or wires
of predetermined width or diameter which obstruct the light from means of illumination
falling on various points along the surface of the helical tubular coils and thus provide
periods of light and darkness for the culture medium circulating in the helical tubular
coils. In a preferred photo bio-reactor said alternating light and darkness time periods on
each point along the flow path of said circulating culture medium are in the ratio 1:0.1 to
1: 0.2. In an embodiment, these coils are wound around a 'wire cage'(2) as illustrated in
Figure 2, which would provide strips of shadow or less light intensity zone at regular
intervals to result in alternating light and darkness time periods on each point along the
flow path. Vertical strips of black-paper at the opposite face of the cage after the tube
may be provided to further ensure reduction in light intensity in that zone. In another
preferred embodiment of photo bio-reactor said means of providing periods of light and
darkness comprises an electronic flashing device. In order to get best results, there is
preferably a cycle comprising alternately continuous darkness time period of 8 hours after
each period of 16 hours of said alternating light and darkness time periods.
The bio reactor has a de-gasser chamber(4) having hydraulic connection with said free
end of the first coaxial coil for removing unwanted gases from said culture medium.
Optionally, a stirrer(S) is provided in said de-gasser chamber for keeping the bio-mass in
suspension in said culture medium. In a preferred embodiment, the stirrer is a magnetic
stirrer or a small air-lift reactor for suspending the culture. The de-gasser chamber has
hydraulic connection with a heat exchanger(6) for controlling temperature of said culture
medium preferably between 25° C and 36° C. The heat exchanger may comprise a water
bath for heating and/ or a chilling unit for cooling.
The water bath may comprise copper coils for flow of said culture medium, fitted inside a
container for water circulation.
The bio reactor has a rneans(7) for causing flow of said culture medium in said coils
without said means coming into direct contact with said medium. In a preferred
embodiment this means is a perislatic pump(7), which acts on the outer surface of the
tube to cause pumping of the culture medium without coming in contact with the
medium. A gas injection means(8) is connected to said de-gasser chamber of the bio
reactor on one end and said free end of last coil on the other end. In a prferred
embodiment the gas injection means may be a Y-shaped junction(8) having two inlet
arms and one outlet arm with said outlet arm connected to said free end of last coil and
said two inlet arms connected to a CO2 source and an air source respectively.The flow of
the air plus carbon-dioxide and the pump together are kept such that the relative
superficial velocity of the gas with respect to the liquid does not exceed the value 0.085
m/s. We can obtain such value by taking air flow rate to be flow rate to be 0.085 m/s. In a preferred embodiment flow rate of said circulating culture
medium is from .085 m/s to 0.10 m/s and said gas flow rate is between 0.170 m/s to 0.200
m/s.
A preferred method of cultivating and harvesting a bio-mass in the photo bio-reactor of
present invention comprises the steps of:
(a) circulating a culture medium containing a micro algae in said reactor at a
predetermined flow rate;
(b) providing alternately period of light and darkness for predetermined time periods on
each point along the flow path of said circulating culture medium;
(c) removing unwanted gases from said circulating culture medium;
(d) controlling temperature of said culture medium between 25° and 36° C;
(e) optionally, stirring said circulating culture medium to keep said micro algae in
suspension;
(f) injecting CO2 and air into said circulating culture medium to ensure a predetermined
gas flow rate;
(g) providing continuous darkness for a predetermined time period on each point along
the flow path of said circulating a culture medium; and
(h) harvesting cultivated micro algae from said circulating culture medium.
The micro algae used is Botryococcus braunii. The method may also be adapted for
cultivating and harvesting spirulina or any other algae.
In the preferred embodiment, the modified Chu-13 medium is used to culture B. braunii.
This medium has the following composition (Kgnr3) at four-fold normal strength:
KN03 (0.2) Copper (0.02ppm)
K2HPO4 (0.04) Cobalt (0.02ppm)
MgS04.7H2O (0.1) Molybdenum (0.02ppm)
CaCl2.6H2O (0.08) Manganese (O.Sppm)
Ferric Citrate (0.01) Boron (O.Sppm)
Citric Acid (0.1)
The production of hydrocarbons in B. braunii appears to be growth associated,
irrespective of the specific culture conditions and the nutrients used. The production of
hydrocarbon is energetically demanding and thus it leads to slow growth rate of algae and
so is not dominated by the amount of nutrients present. The color of algal colonies is
dependent on the carotenoid-to-chlorophyll ratio, which is affected by the intensity of
light. Carbohydrates concentration, cellular nitrogen, and phosphorus content of B.
brauni are decreased by extended exposure to a light intensity.
Colony size increase with increased light intensity initially when the cell concentration is
low and sufficient light for photosynthesis was available. As the cell concentration
increase, the average light intensity within the photobioreactor decreased because of
mutual shading, and thus the production rates of extracellular polysaccharides and
hydrocarbons decrease with decreasing average light intensity. The equilibrium colony
size is determined by a dynamic balance between the mechanical strength of colonies and
the hydrodynamics stress due to turbulence in the reactors.
The pH of the culture medium is generally adjusted to between 7.4 and 7.6 before
inoculation. A regular increase in pH is observed during active growth followed by a
slight decline later. The increase in pH is partly due to the consumption of dissolved CO2
for photosynthesis. Similar changes in pH are observed in CO2 enriched culture during
exponential growth.
Potentially domestic sewage that has been pretreated by activated sludge treatment can be
used as a medium for hydrocarbon production by B. braunii. Sewage can reduce the cost
of producing the hydrocarbons. Secondary stage-treated sewage (STS) has been
characterized, and found to contain a large amount of nitrogen (as nitrate) and phosphorus
(as phosphates). Botryococcus cannot grow on industrial wastewater containing a high
concentration of inorganic ions. Potentially, the productivity of continuous algal culture
can be improved by optimizing the dilution rate. The optimal dilution rate is expected to
depend on the strength of wastewater and the intensity of illumination.
The pH is adjusted to 7.5 before sterilization. Optimum temperature for growth is 25-30°
C. Reviews of the different techniques available (flocculation, filtration, centnfugation
and air flotation) have concluded that centnfugation is possibly the most reliable
technique and only slightly more expensive than other techniques.
Here we have assumed that the goal of microalgal biotechnology efforts to recover a high
value product from the microalgal biomass. Thus, the high value product needs to be
separated from the biomass. Depending on the process, the microalgal cells may need to
be physically disrupted. Both ball mills and high pressure homogenisers have been used
successfully to disrupt microalgal cells to enhance recovery.
Depending on the product to be recovered, in the process it might entail reducing the
water content of the microalgal biomass. Absence of water in the biomass enhances the
recovery of lipid soluble components . Microalgal mass can be dehydrated in spray
dryers, drum dryers, freeze dryers and sun dryers. In the case of Heat sensitive
compounds commercial producers have developed technologies that limit exposure to
conditions known to cause degradation.
In some cases the biomass may not need to be dehydrated, and the extraction and
fractionation can be carried out on the wet biomass. Further downstream processing may
be needed to isolate the active compound depending on the intended final product.
Use of solvents and enzymes might help with cellular disruption and product recovery but
care must be taken regarding what aids are used if the product is intended for human
consumption.
NIES-N-836. B. braunii, sourced from Japan (NIES culture collection centre) was
obtained from Central Food Technological Research Institute, Mysore, India and was
used for evaluation of the performace of the reactor and other studies.
Example 1
In order to inroduce flash light effect, a wire strip is intermittently interposed between
light source and tube. In an embodiment, for every tubular length of 2.3 cm the wire strip
has a thickness of 0.3 cm.
Thus Flash-Lighi effective ratio = time in darkness / time in light = 0.3/2.0 =1: 0.15
Example 2
The Biomass estimation is carried out by the following steps:
1. 25ml. medium is harvested.
2. Take eppendorf and pre-weigh it.
3. Transfer the pellet into eppendorf and lyophilize.
4. Weigh the eppendorf again. The difference hi weights is the weight of the biomass.
Hydrocarbon estimation by gravimetric method:
1. Sonicate known quantity of biomass in n-hexane for 30 min.
2. Centrifuge and take the supernatant in pre-weighed vials and evaporate the solvent
under nitrogen to complete dryness.
3. Repeat the extraction 2 more times, pool the solvents and evaporate to complete
dryness with nitrogen.
4. The weight of hydrocarbons is calculated by the difference in the weight of vial.
Determination of growth of B. braunii:
The doubling time for biomass growth rate in the exponential phase is found to be nearly
8-9 days at 27°C and 14-15 days at 31°C as shown in the Figure 5 and 3 respectively. The
hydrocarbon accumulation was found to be growth associated and comprised 50-55% of
the cell mass as shown in Figures 4 and 6.

I CLAIM:
1. A photo bio-reactor for cultivating and harvesting a bio-mass suitable for
producing hydrocarbon comprising:
(i) a helical tubular system having a plurality of substantially coaxial helical transparent tubular coils(l), which could be easily autoclaved, for flow of a culture medium containing micro algae to be cultivated, each coil being hydraulically connected to its adjacent coaxial coil, said coils having annular spaces interposed between the adjacent coils and a space enclosed by the inner diameter of innermost coil, the first and the last coil each having a free end;
(ii) a means (2) of providing periods of light and darkness on each point alternately for predetermined time periods on the inner and outer surfaces of each of said coil;
(iii) a de-gasser chamber (4) having hydraulic connection with said free end of first coil (1) for removing unwanted gases from said culture medium;
(iv) optionally, a stirrer (5) or 'perfusion air-lift reactor' (5) provided in said de-gasser chamber(4) for keeping the bio-mass in suspension in said culture medium;
(v) said de-gasser chamber (4) having hydraulic connection with a heat exchanger (6) for controlling temperature of said culture medium;
(vi) a means (7) for causing flow of said culture medium in said coils without said means coming into direct contact with said medium; and
(vii) a gas injection means (8) connected to said de-gasser chamber (6) on one end and said free end of last coil on the other end.
2. A photo bio-reactor as claimed in claim 1, wherein said transparent
autoclavable tubular coils comprise silicone polymer material.

3. A photo bio-reactor as claimed in claim 1, wherein said means of providing light comprises incandescent lighting device selected from a plurality of tube-lights, light emitting diodes and optical fibers or a combination thereof.
4. A photo bio-reactor as claimed in claim 1, wherein said means of providing period of darkness comprises a plurality of opaque strips or wires of predetermined width or diameter.
5. A photo bio-reactor as claimed in claim 1, wherein said means of providing
periods of light and darkness comprises an electronic flashing device.
6. A photo bio-reactor as claimed in claim 1, wherein said stirrer is a magnetic stirrer or a 'perfusion air-lift reactor'.
7. A photo bio-reactor as claimed in claim 1, wherein said heat exchanger comprises a water bath for heating and/ or a chilling unit for cooling.
8. A photo bio-reactor as claimed in claim 7, wherein said water bath comprises copper coils for flow of said, culture medium, fitted inside a container for water circulation.
9. A photo bio-reactor as claimed in claim 1, wherein means for causing flow of said culture medium comprises a peristaltic pump or any pump maintaining sterile condition.
10. A photo bio-reactor as claimed in claim 1, wherein gas injection means comprises a Y-shaped junction having two inlet arms and one outlet arm with said outlet arm connected to said free end of last coil and said two inlet arms connected to a CO2 source and an air source respectively.
11. A method of cultivating and harvesting a bio-mass in a photo bio-reactor as claimed in claim 1, comprising the steps of:

(a) circulating a culture medium containing a micro algae in said reactor at a
predetermined flow rate;
(b) providing alternately period of light and darkness for predetermined time
periods on each point along the flow path of said circulating culture
medium;
(c) removing unwanted gases from said circulating culture medium;
(d) controlling temperature-of said culture medium between 25° and 36° C;
(e) optionally, stirring said circulating culture medium to keep said micro algae in suspension;
(f) injecting CO2 and air into said circulating culture medium to ensure a predetermined gas flow rate;
(g) providing continuous darkness for a predetermined time period on each point along the flow path of said circulating a culture medium; and
(h) harvesting cultivated micro algae from said circulating culture medium.
12. A method as claimed in claim 11, wherein said micro algae is Botryococcus
braunli
13. A method as claimed in claim 12, wherein said culture medium is a modified
Chu-13 medium.
14. A method as claimed in claim 11, wherein said alternating light and darkness time periods on each point along the flow path of said circulating culture medium are in the ratio 1:0.1 to 1:0.2.
15. A method as claimed in claim 11, wherein flow rate of said circulating culture medium is from .085 m/s to 0.10 m/s.

16. A method as claimed in claim 11, wherein said gas flow rate is between 0.170 m/s to 0.200 m/s.
17. A method as claimed in claim 11, wherein said continuous darkness time period is 8 hours after each period of 16 hours comprising said alternating light and darkness time periods,
18. A method as claimed in claim 11 as and when used for cultivating spirulina.

Documents:

1135-DEL-2006-Abstract-(28-12-2011).pdf

1135-del-2006-abstract.pdf

1135-DEL-2006-Claims-(23-04-2012)..pdf

1135-DEL-2006-Claims-(23-04-2012).pdf

1135-DEL-2006-Claims-(28-12-2011).pdf

1135-del-2006-claims.pdf

1135-DEL-2006-Correspondence Others-(19-04-2012).pdf

1135-DEL-2006-Correspondence Others-(23-04-2012)..pdf

1135-DEL-2006-Correspondence Others-(23-04-2012).pdf

1135-DEL-2006-Correspondence Others-(28-12-2011).pdf

1135-DEL-2006-Correspondence-Others-(04-05-2010).pdf

1135-DEL-2006-Correspondence-Others-(11-05-2011).pdf

1135-DEL-2006-Correspondence-Others-(21-07-2006).pdf

1135-del-2006-correspondence-others-1.pdf

1135-del-2006-correspondence-others.pdf

1135-del-2006-description (complete).pdf

1135-del-2006-drawings.pdf

1135-del-2006-form-1.pdf

1135-del-2006-form-13-(26-10-2006).pdf

1135-del-2006-form-13.pdf

1135-DEL-2006-Form-18-(21-07-2006).pdf

1135-del-2006-form-18.pdf

1135-del-2006-form-2.pdf

1135-del-2006-form-26.pdf

1135-DEL-2006-Form-9-(21-07-2006).pdf

1135-DEL-2006-GPA-(28-12-2011).pdf

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Patent Number

252085

Indian Patent Application Number

1135/DEL/2006

PG Journal Number

17/2012

Publication Date

27-Apr-2012

Grant Date

25-Apr-2012

Date of Filing

08-May-2006

Name of Patentee

ABHISHEK NARAIN SINGH

Applicant Address

EB-02, Vindhyachal Hostel, IIT Delhi, Hauz khas, Delhi-110016

Inventors:

#	Inventor's Name	Inventor's Address
1	ABHISHEK NARAIN SINGH,	EB-2, Vindhyachal Hostel, IIT Delhi, INDIA.

PCT International Classification Number

A01G7/00

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1			NA