Patent application number | Description | Published |
20090081742 | HIGH EFFICIENCY SEPARATIONS TO RECOVER OIL FROM MICROALGAE - A system and method for processing algae cells to create biofuel are disclosed. Specifically, the system and method utilize steam to rupture algae cells in order to utilize intracellular oil therein. The system includes a conduit for growing algae cells and a generator for creating steam. Further, the system includes a lysing device that mixes the algae cells and the steam to rupture the algae cells. In order to maximize the efficiency of the lysing process, the system may further include a heat exchanger for preheating the algae cells with the lysed cells. In addition, the system includes a bioreactor to synthesize biofuel from the unbound oil. | 03-26-2009 |
20100330653 | Method for Nutrient Pre-Loading of Microbial Cells - A method is provided for supporting the growth of selected microbial cells and for obstructing the growth of contaminants in a non-sterile system. In the method, the microbial cells are pre-loaded with a surplus amount of a chosen nutrient, such as phosphorus, other macronutrients, or micronutrients. Further, the chosen nutrient is greatly reduced, or eliminated, from the non-sterile system. Thereafter, the pre-loaded selected microbial cells are introduced into the non-sterile system. In the non-sterile system, the selected microbial cells rely on the surplus amount of the chosen nutrient to survive and grow. At the same time, contaminants such as non-selected microbial strains and bacteria starve from a lack of the chosen nutrient in the non-sterile system. | 12-30-2010 |
20110034751 | HYDROLYSIS SYSTEM AND PROCESS FOR DEVICES CONTAINING ENERGETIC MATERIAL - A system for chemically disposing energetic material enclosed in assembled devices includes a porous basket. The porous basket forms an enclosed chamber for receiving the assembled devices. Further, the basket is supported by a rotatable basket arm that is, in turn, connected to a lifting arm. In addition to these structures, the system includes a tank that holds a hydrolysis solution. The tank is positioned to allow the lifting arm to submerge the basket into the solution. After submersion, the basket arm rotates the basket in the solution to flow the hydrolysis solution into contact with the assembled devices therein. As a result, the assembled devices react with the solution so that the solution penetrates the assembled devices, allowing the solution to contact and react with the energetic material to render the energetic material non-energetic. | 02-10-2011 |
20110287531 | Microalgae Growth Pond Design - A raceway pond for circulating microalgae in a fluid medium includes a plurality of interconnected channels. Each channel is straight and has a structured gradient, due to tilt or terracing, that moves the fluid medium along the raceway. In operation, the concentration of microalgae in the fluid medium is maintained substantially constant, and the depth of the fluid medium in the raceway is maintained below a pre-determined level. | 11-24-2011 |
20110308144 | Algae Biofuel Carbon Dioxide Distribution System - A system and method for producing biofuel from pollutant-fed algae are disclosed. Specifically, the system includes a scrubber with a chamber for receiving a pollutant-contaminated fluid stream. Further, a scrubber solution is received in the chamber for scrubbing the pollutant-contaminated fluid stream. Also, the system includes a bioreactor that is provided with an input port to receive the scrubber solution with pollutants for use as nutrients to support algae cell growth. Further, the system includes an algae separator that removes the algae from the bioreactor and a device for processing the algae into biofuel. In order to recycle the scrubber solution, the algae separator is in fluid communication with the scrubber. With this arrangement, the effluence from the bioreactor may be recycled for use as the scrubber solution. | 12-22-2011 |
20110308149 | System for Supporting Algae Growth with Adsorbed Carbon Dioxide - A system is provided for supporting algae growth with adsorbed carbon dioxide. In the system, a channel such as a raceway is provided and holds bicarbonate solution. As algae grows in the solution, it is converted into carbonate solution. Therefore, the system provides a high surface area liquid gas contact medium for converting the carbonate solution back into bicarbonate solution. Specifically, the carbonate solution from the channel is delivered to the contact medium. At the contact medium, the carbonate solution drips or slowly moves along while air, containing carbon dioxide, moves across the solution. As carbon dioxide is adsorbed by the solution, it converts back into bicarbonate solution. Then, the bicarbonate solution is fed back into the channel to support further algae growth. | 12-22-2011 |
20110318815 | Method and System for Growing Microalgae in an Expanding Plug Flow Reactor - A method and system are provided for supporting the growth of algae cells. In the method, an inoculum of algae cells are grown in a closed bioreactor. Thereafter, the inoculum of algae cells is passed into an open system. Specifically, the inoculum is passed into an expanding plug flow reactor (EPFR) having an increasing width from its first to its second end. Further, medium is introduced into the EPFR to maintain a selected shallow depth. Importantly, the medium provides sufficient nutrients to support logarithmic growth of the algae cells to maintain a high concentration of algae cells, i.e., at least 0.5 grams per liter of medium, in the EPFR. After the desired level of growth is reached, the algae cells are transferred to a standard plug flow reactor wherein oil production is activated in the algae cells. | 12-29-2011 |
20110318816 | SYSTEM FOR MODERATING THE TEMPERATURE OF A MEDIUM FOR GROWING MICROALGAE - A system is provided for moderating the temperature of a medium for growing microalgae and for distilling fresh water. In the system, the medium flows through a conduit having two ends and a bottom. As the sunlight passes into the medium, the algae grows and the medium is heated. For the system, an impermeable first liner is extended across the conduit to cover the bottom of the conduit. Further, a gas permeable/liquid impermeable second liner is extended across the conduit to cover the bottom of the conduit. With the second liner positioned on top of the first liner, vapor medium is only able to pass through the second liner. Also, a condensing mechanism is positioned between the first and second liners. Any vapor medium that passes through the second liner is condensed into fresh water. As a result, fresh water is distilled and the medium is cooled through condensation. | 12-29-2011 |
20120028346 | Microalgae Photobioreactor - A bioreactor is provided for circulating a fluid medium. To reduce manufacturing and maintenance expenses, the bioreactor is formed from two sheets of transparent plastic. Structurally, each sheet has first and second edges extending in an axial direction between proximal and distal ends. To form the bioreactor, the sheets are sealed to one another along their respective first edges, distal ends, and second edges. Also, the sheets are sealed to one another along an axially-extending boundary positioned between the first and second edges. As a result, a substantially U-shaped channel is defined between the first and second sheets. Further, two side-by-side openings to the channel are defined by the proximal ends of the sheets. Also, the bioreactor includes a conduit interconnecting the first opening and the second opening. A pump is positioned in the conduit to circulate the fluid medium through the channel. | 02-02-2012 |
20120045800 | Microalgae Biofuel Production System - A system for processing oil from algae is disclosed. Specifically, the system recycles byproducts of the process for use as nutrients during algae growth and oil production. The system includes a conduit for growing algae and an algae separator that removes the algae from the conduit. Also, the system includes a device for lysing the algae and an oil separator to remove the oil from the lysed matter. Further, the system includes a biofuel reactor that receives oil from the oil separator and synthesizes biofuel and glycerin. Moreover, the algae separator, oil separator and biofuel reactor all recycle byproducts back to the conduit to support further algae growth. | 02-23-2012 |
20120077234 | METHOD AND SYSTEM FOR MICROBIAL CONVERSION OF CELLULOSE TO FUEL - A method and system are provided for producing biofuel from cellulosic feedstock. In the method, the cellulosic feedstock is pretreated to separate cellulose, hemicellulose, and lignin. Thereafter, the cellulose and hemicellulose are converted into sugars through enzymatic hydrolysis. Then, the sugars are converted into lipids, e.g. triglycerides, through a microbial process. Specifically, heterotrophic microalgae is grown on the triglycerides and forms triglycerides. While triglycerides are formed from the cellulose and hemicellulose, the lignin is converted into ringed hydrocarbons, such as aromatic hydrocarbons and cycloalkanes, e.g., cycloparaffins. To form the biofuel, the triglycerides and ringed hydrocarbons are processed together. During this step, the triglycerides are converted into straight chain paraffins and esters. Preferably, the biofuel is a surrogate for jet quality JP-8 fuel. | 03-29-2012 |
20120202242 | System and Method for Non-Sterile Heterotrophic Algae Growth - A system and method for non-sterile heterotrophic algae growth is provided. The system includes a first Continuous Stirred Tank Reactor (CSTR), kept under sterile conditions, for mixing a full load nutrient with algae cells to create a culture. After being transferred to a first Plug Flow Reactor (PFR), a nutrient is depleted from the culture to create an effluent. By depleting the nutrient, algae cells are able to grow more rapidly without having to compete with other microbes for available nutrients. Once the effluent is created, it is transferred to a second PFR where organic carbon is added. By adding organic carbon, the algae cells grow intracellular oil rapidly. Algae cells are then removed for processing into biofuel. | 08-09-2012 |
20120295336 | Microalgae Cultivation System for Cold Climate Conditions - A system and method are provided for growing microalgae in cold climate areas. The system includes an expanding Plug Flow Reactor with a plurality of ponds used to grow algae by mixing a culture fluid with a nutrient. To minimize the loss of heat due to environmental factors, the expanding Plug Flow Reactor is covered with a translucent, light-transmitting cover and is lined with an insulation liner. In addition, an underground sump and pump are provided and connected to the expanding Plug Flow Reactor. The sump is provided to store the algae at night when ambient air temperature is at its coldest. An adjacent power plant provides: (1) heat byproducts to warm the culture and (2) CO | 11-22-2012 |
20130029403 | System and Method for Using a Pulse Flow Circulation for Algae Cultivation - A system and method for using a pulse flow to circulate algae in an algae cultivation apparatus are provided. In order to counteract the negative effects of biofouling on algae cultivation equipment, a pulse flow is created to periodically move through an algae cultivation apparatus. The pulse flow will dislodge algae cells adhering to various surfaces of the apparatus, and it will also create turbulence to stir up any algae cells which may have settled onto the bottom of the apparatus. To produce an increased fluid flow rate required to create an effective pulse flow, a sump, which is periodically filled with drawn algal culture from the apparatus, is located at an elevated position above the apparatus. When released, the algal culture travels through a transfer pipe and into the apparatus with gravity causing the algal culture to flow at a very high rate. | 01-31-2013 |
20130061517 | Method for Growing Microalgae from Wastewater for Oil Production - A method is provided for growing microalgae from wastewater for oil production in a three-step wastewater treatment facility. In the method, two carbon sources are selected for addition to the wastewater, which contains naturally-occurring bacteria. Specifically, the first carbon source is selected to increase the carbon-to-nitrogen ratio and the carbon-to-phosphorous ratio within the microalgae. The first carbon source serves as a food source for the microalgae, and the second carbon source promotes the breakdown of carbon nitrogen and phosphorous by the bacteria cells into a more easily digestible form for the microalgae. Due to the added carbon, the wastewater supports growth of the microalgae and the production of oils therein. | 03-14-2013 |
20130196392 | MICROALGAE BIOFUEL PRODUCTION SYSTEM - A system for processing oil from algae is disclosed. Specifically, the system involves the use of a consortium of algae strains as its input, wherein each algae strain has a unique characteristic for resisting/dominating a particular operational/environmental factor. Also, the system recycles byproducts of the process for use as nutrients during algae growth and oil production. The system includes a conduit for growing algae and an algae separator that removes the algae from the conduit. Also, the system includes a device for lysing the algae and an oil separator to remove the oil from the lysed matter. Further, the system includes a biofuel reactor that receives oil from the oil separator and synthesizes biofuel and glycerin. Moreover, the algae separator, oil separator and biofuel reactor all recycle byproducts back to the conduit to support further algae growth. | 08-01-2013 |
20130217082 | Algae Biofuel Carbon Dioxide Distribution System - A closed-loop system for growing algae in a bioreactor is disclosed, for example, to produce biofuel. An aqueous bioreactor solution is formulated such that the principal source of carbon for algae growth is supplied by sodium bicarbonate. During algae growth in the aqueous solution, the concentration of sodium bicarbonate in the solution is reduced while the concentration of sodium carbonate increases. A regenerator is provided to regenerate sodium bicarbonate from the sodium carbonate. Specifically, after sufficient growth, the algae are concentrated and an algae depleted media is produced. Carbon dioxide is then introduced into the algae depleted media to regenerate sodium bicarbonate from the sodium carbonate. The regenerated sodium bicarbonate is then recycled into the bioreactor to supply carbon for further algae growth. | 08-22-2013 |
20140030796 | System and Method for Using a Pulse Flow Circulation for Algae Cultivation - A system and method for using a pulse flow to circulate algae in an algae cultivation apparatus are provided. In order to counteract the negative effects of biofouling on algae cultivation equipment, a pulse flow is created to periodically move through an algae cultivation apparatus. The pulse flow will dislodge algae cells adhering to various surfaces of the apparatus, and it will also create turbulence to stir up any algae cells which may have settled onto the bottom of the apparatus. To produce an increased fluid flow rate required to create an effective pulse flow, a sump, which is periodically filled with drawn algal culture from the apparatus, is located at an elevated position above the apparatus. When released, the algal culture travels through a transfer pipe and into the apparatus with gravity causing the algal culture to flow at a very high rate. | 01-30-2014 |
20140248601 | Method and System for Growing Microalgae in an Expanding Plug Flow Reactor - A method and system are provided for supporting the growth of algae cells. Initially, an inoculum of algae cells are grown in a closed bioreactor. Thereafter, the inoculum is passed into an open Expanding Plug Flow Reactor (EPFR). Growth medium is added at a plurality of locations along the EPFR. This addition is controlled in response to the growth rate of the algae cells to maintain a substantially same concentration of cells at each location in the EPFR. At all times, the medium provides sufficient nutrients to support growth and maintain a high concentration of algae cells, i.e., at least 0.5 grams per liter of medium, in the EPFR. After the desired level of growth is reached, the algae cells are transferred from the EPFR to a standard plug flow reactor wherein oil production is activated in the algae cells. | 09-04-2014 |
20140322805 | System and Method for Using a Pulse Flow Circulation for Algae Cultivation - A device for generating a pulsed flow in a channel containing a circulating algal culture can include a plate that is pivotably mounted on the channel and an activator. A pulsed flow is generated in the channel by first positioning the plate to impede the flow of circulating algal culture and then rotating the plate to a submerged position. The pulsed flow can be employed to counteract the negative effects of bio-fouling on algae cultivation equipment. In another arrangement, a device for generating a pulsed flow in a sloped raceway that is in fluid communication with a sump can include a gate. In different embodiments, the gate can operate as a so-called “pinch gate” or as a so-called “overflow gate.” In another aspect, a variable rate pump, such as a centrifugal pump, a screw pump or an airlift pump, is described for establishing a pulsed flow in a channel. | 10-30-2014 |