Patent application number | Description | Published |
20140261213 | Carbon Dioxide Control System for Aquaculture - Some embodiments provide a recirculating aquaculture system for aquatic life. The system includes a culture tank, a sensor configured to measure a carbon dioxide concentration in the culture tank, a variable speed pump configured to circulate water through the culture tank, and a controller in communication with the sensor and the variable speed pump. The controller is configured to retrieve a maximum carbon dioxide concentration in the culture tank, retrieve a current carbon dioxide concentration, and compare the current carbon dioxide concentration to the maximum carbon dioxide concentration. When the current carbon dioxide concentration is greater than the maximum carbon dioxide concentration, the controller is configured to automatically increase the current water flow rate or automatically increase the current air flow rate based on the current gas to liquid ratio in the system. | 09-18-2014 |
20140311416 | Dissolved Oxygen Control System for Aquaculture - Some embodiments provide a recirculating aquaculture system for aquatic life. The system includes a culture tank, a sensor configured to measure a current dissolved oxygen level in the culture tank, a variable speed pump configured to circulate water through the culture tank, and a controller in communication with the sensor and the variable speed pump. The controller is configured to retrieve a dissolved oxygen threshold level and a maximum gas to liquid ratio in the culture tank, retrieve the current dissolved oxygen level, compare the current dissolved oxygen level with the dissolved oxygen threshold level, and automatically increase one of a current water flow rate and a current oxygen flow through the system when the current dissolved oxygen level is less than the dissolved oxygen threshold level. | 10-23-2014 |
20140311417 | Method for Regulating Energy Consumption in Aquaculture Systems - Some embodiments provide a recirculating aquaculture system for aquatic life. The system includes a culture tank, a plurality of sensors configured to control parameters in the system, a variable speed pump configured to circulate water through the culture tank, and a controller in communication with the plurality of sensors and the variable speed pump. The controller is configured to prioritize the plurality of control parameters based on a hierarchy list, select a highest priority control parameter, determine potential actions for each of the plurality of control parameters, and select a highest priority action based on at least one of the hierarchy list, the highest priority control parameter, a current power consumption of the variable speed pump, time of day, feeding cycle of the aquatic life, and resting cycles of the aquatic life. The controller is also configured to execute the highest priority action. | 10-23-2014 |
20140311974 | Ammonia Control System for Aquaculture - Some embodiments provide a recirculating aquaculture system for aquatic life. The system includes a culture tank, a first sensor configured to measure a current ammonia concentration in the culture tank, a biofilter in fluid communication with the culture tank, a variable speed pump configured to circulate water through the culture tank and the biofilter, and a controller in communication with the first sensor and the variable speed pump. The controller is configured to retrieve a maximum ammonia concentration, retrieve the current ammonia concentration from the first sensor, and compare the current ammonia concentration to the maximum ammonia concentration. The controller is also configured to control the variable speed pump to increase a current water flow rate through the system when the current ammonia concentration is greater than the maximum ammonia concentration. | 10-23-2014 |
20140346125 | Desalting Salty Sludge System and Method - A system and method of desalting salty sludge is provided. The method includes providing a salty sludge; processing the salty sludge to increase its surface area; adding water to the salty sludge to make a sludge slurry and to wash the salty sludge; removing and purifying degraded water from the sludge slurry, and recirculating purified water into the sludge slurry; separating a liquid phase and a solid phase of the sludge slurry and purifying the liquid phase; identifying a salt concentration in the solid phase and comparing the salt concentration to a desired value; and adding water to the solid phase if the salt concentration is greater than the desired value. | 11-27-2014 |