Patent application number | Description | Published |
20120311317 | Access-controlled customer data offloading to blind public utility-managed device - A method and system for access-controlled customer data offloading uses a blind public utility-managed device. A customer-managed device encrypts collected customer data using per-type, per-period keys and transmits the encrypted customer data to the utility-managed device. The customer-managed device further encrypts the per-type, per-period keys using a master key and transmits the encrypted per-type, per-period keys to the utility-managed device. When the current period ends (e.g., each day at midnight), the customer-managed device generates new per-type, per-period keys and continues the above customer data offloading using the new per-type, per-period keys. As a result, the customer offloads storage of customer data to the public utility without relinquishing control over access to the customer data. Moreover, the fact that the customer data are encrypted by data type and period allows the customer to access and expose the customer data in highly granular fashion. | 12-06-2012 |
20130013118 | Thermostat with Set Point Range Feedback - A thermostat user interface (UI) is provided for presenting calculated set point ranges. The thermostat UI has a major thermostat scale for presenting a current temperature and an overall range of feasible temperatures. A set point indictor indicates a set point input (e.g., desired temperature) with respect to the major thermostat scale. A minor thermostat scale presents a set point range, where the set point range is a range of permitted temperature measurement variations from the set point input. The set point range brackets the set point indicator with a maximum temperature value representing a highest temperature in the set point range, and a minimum temperature value representing a lowest temperature in the set point range. If high and low temperature set point indictors are used, then there are first and second minor thermostat scales bracketing, respectively, the high and low temperature set point indicators. | 01-10-2013 |
20130013119 | Virtual Thermostat System and Method - A virtual thermostat system and method are provided. The method accepts commands via a virtual thermostat interface for establishing temperature set points for a plurality of zones. Energy consumption information is also accepted from a plurality of energy consumption units. Each unit consumes energy at an associated peak power to supply a controlled temperature medium to a corresponding zone. The method also accepts temperature measurements for each zone. Then, consumption commands are sent to each energy consumption unit in response to associated zone temperature set points, while insuring that a combined peak power of the energy consumption units is less than a maximum peak power threshold. In one aspect, the virtual thermostat accepts temperature measurements from a plurality of physical thermostats, each associated with an energy consumption unit. Then, consumption commands are relayed to the energy consumption units via associated physical thermostats. | 01-10-2013 |
20130013124 | System and Method for the Multi-Dimensional Representation of Energy Control - A multi-dimensional energy control system is provided with an energy management software application that organizes the consumption of energy by a device as an n-dimensional energy space, where n is an integer greater than 2, and each axis in the energy space represents an energy consumption characteristic. The energy management application generates instructions for a device in response to calculating a compromise operating point in the energy space. A user interface (UI) connected to the energy management application has a display to receive a graphical representation of the energy space and compromise operating point, and an input to receive user commands for moving the represented compromise operating point in the represented energy space. The energy management application calculates the compromise operating point in the energy space to match the displayed compromise operating point. | 01-10-2013 |
20130211751 | System and Method for Calculating Power Using Contactless Voltage Waveform Shape Sensor - A system and method are provided for calculating power using a voltage waveform shape measurement from a contactless sensor. An electrically conductive medium carries alternating current (AC) electrical current, associated with an AC voltage, from a source node to a destination node. AC current is measured through the electrically conductive medium. Using a contactless sensor, an AC voltage waveform shape is measured. The power usage at the destination node is calculated in response to the AC current measurement, the measurement of the AC voltage waveform shape, and an AC voltage potential. For simplicity, the AC current and AC voltage waveform shape may both be measured at a first node located between the source node and the destination node. The AC voltage potential used in the power usage calculation may be an estimate, an actual measurement, or a value supplied by an external source (e.g., the power utility). | 08-15-2013 |
20140214228 | Graphical User Interface for the Multi-Dimensional Representation of Energy Control - A multi-dimensional energy control system is provided with an energy management software application that organizes the consumption of energy by a device as an n-dimensional energy space, where n is an integer greater than 2, and each axis in the energy space represents an energy consumption characteristic. The energy management application generates instructions for a device in response to calculating a compromise operating point in the energy space. A user interface (UI) connected to the energy management application has a display to receive a graphical representation of the energy space and compromise operating point, and an input to receive user commands for moving the represented compromise operating point in the represented energy space. The energy management application calculates the compromise operating point in the energy space to match the displayed compromise operating point. | 07-31-2014 |
Patent application number | Description | Published |
20130025281 | GASIFICATION SYSTEM AND METHOD - A system configured for the production of at least one product selected from the group consisting of syngas, Fischer-Tropsch synthesis products, power, and chemicals, the system comprising a dual fluidized bed gasification apparatus and at least one apparatus selected from power production apparatus configured to produce power from the gasification product gas, partial oxidation reactors configured for oxidation of at least a portion of the product gas, tar removal apparatus configured to reduce the amount of tar in the product gas, Fischer-Tropsch synthesis apparatus configured to produce Fischer-Tropsch synthesis products from at least a portion of the product gas, chemical production apparatus configured for the production of at least one non-Fischer-Tropsch product from at least a portion of the product gas, and dual fluidized bed gasification units configured to alter the composition of the product gas. Methods of operating the system are also provided. | 01-31-2013 |
20130028801 | GASIFICATION SYSTEM AND METHOD - A system configured for the production of at least one product selected from the group consisting of syngas, Fischer-Tropsch synthesis products, power, and chemicals, the system comprising a dual fluidized bed gasification apparatus and at least one apparatus selected from power production apparatus configured to produce power from the gasification product gas, partial oxidation reactors configured for oxidation of at least a portion of the product gas, tar removal apparatus configured to reduce the amount of tar in the product gas, Fischer-Tropsch synthesis apparatus configured to produce Fischer-Tropsch synthesis products from at least a portion of the product gas, chemical production apparatus configured for the production of at least one non-Fischer-Tropsch product from at least a portion of the product gas, and dual fluidized bed gasification units configured to alter the composition of the product gas. Methods of operating the system are also provided. | 01-31-2013 |
20130028802 | GASIFICATION SYSTEM AND METHOD - A system configured for the production of at least one product selected from the group consisting of syngas, Fischer-Tropsch synthesis products, power, and chemicals, the system comprising a dual fluidized bed gasification apparatus and at least one apparatus selected from power production apparatus configured to produce power from the gasification product gas, partial oxidation reactors configured for oxidation of at least a portion of the product gas, tar removal apparatus configured to reduce the amount of tar in the product gas, Fischer-Tropsch synthesis apparatus configured to produce Fischer-Tropsch synthesis products from at least a portion of the product gas, chemical production apparatus configured for the production of at least one non-Fischer-Tropsch product from at least a portion of the product gas, and dual fluidized bed gasification units configured to alter the composition of the product gas. Methods of operating the system are also provided. | 01-31-2013 |
20130030062 | GASIFICATION SYSTEM AND METHOD - A system configured for the production of at least one product selected from the group consisting of syngas, Fischer-Tropsch synthesis products, power, and chemicals, the system comprising a dual fluidized bed gasification apparatus and at least one apparatus selected from power production apparatus configured to produce power from the gasification product gas, partial oxidation reactors configured for oxidation of at least a portion of the product gas, tar removal apparatus configured to reduce the amount of tar in the product gas, Fischer-Tropsch synthesis apparatus configured to produce Fischer-Tropsch synthesis products from at least a portion of the product gas, chemical production apparatus configured for the production of at least one non-Fischer-Tropsch product from at least a portion of the product gas, and dual fluidized bed gasification units configured to alter the composition of the product gas. Methods of operating the system are also provided. | 01-31-2013 |
20130030064 | GASIFICATION SYSTEM AND METHOD - A system configured for the production of at least one product selected from the group consisting of syngas, Fischer-Tropsch synthesis products, power, and chemicals, the system comprising a dual fluidized bed gasification apparatus and at least one apparatus selected from power production apparatus configured to produce power from the gasification product gas, partial oxidation reactors configured for oxidation of at least a portion of the product gas, tar removal apparatus configured to reduce the amount of tar in the product gas, Fischer-Tropsch synthesis apparatus configured to produce Fischer-Tropsch synthesis products from at least a portion of the product gas, chemical production apparatus configured for the production of at least one non-Fischer-Tropsch product from at least a portion of the product gas, and dual fluidized bed gasification units configured to alter the composition of the product gas. Methods of operating the system are also provided. | 01-31-2013 |
20150232769 | GASIFICATION SYSTEM AND METHOD - A method including introducing a carbonaceous feedstock and a heated heat transfer material into a gasifier, whereby at least a portion of the carbonaceous material is pyrolyzed; removing a gasification product gas comprising, entrained therein, char, particulate heat transfer material, and optionally unreacted carbonaceous feedstock; separating a solids product comprising char, heat transfer material and optionally unreacted carbonaceous material from the gasification product gas; heating at least a portion of the solids product via a combustor, thus producing a heated portion of the solids product and a combustor flue gas, wherein a portion of the heat for heating is obtained via combustion of the char; separating the heated portion from the flue gas, and introducing the separated heated portion into the gasifier, providing heat for pyrolysis; and utilizing at least a portion of the gasification product gas for Fischer-Tropsch synthesis and/or power production. | 08-20-2015 |
Patent application number | Description | Published |
20130105008 | SEAL POT DESIGN | 05-02-2013 |
20130109765 | GASIFIER FLUIDIZATION | 05-02-2013 |
20130161563 | SUPPLEMENTAL FUEL TO COMBUSTOR OF DUAL FLUIDIZED BED GASIFIER - A method of gasification by introducing a feed material to be subjected to gasification into a dual fluidized bed gasifier comprising a pyrolyzer fluidly connected with a combustor such that a circulation stream comprising a heat transfer material can be continuously circulated between the pyrolyzer, in which the temperature of the circulation stream is reduced, and the combustor, in which the temperature of the circulation stream is increased, wherein the pyrolyzer is operable to convert at least a portion of the feed material into a gasifier product gas comprising hydrogen and carbon monoxide, and wherein the combustor is operable to increase the temperature of the circulation stream via combustion of char introduced thereto with the circulation stream and at least one supplemental fuel. A system for carrying out the method is also provided. | 06-27-2013 |
20130165534 | SYSTEM AND METHOD FOR PRODUCTION OF FISCHER-TROPSCH SYNTHESIS PRODUCTS AND POWER - A method for generation of power and Fischer-Tropsch synthesis products by producing synthesis gas comprising hydrogen and carbon monoxide, producing Fischer-Tropsch synthesis products and Fischer-Tropsch tailgas from a first portion of the synthesis gas, and generating power from a second portion of the synthesis gas, from at least a portion of the Fischer-Tropsch tailgas, or from both. The method may also comprise conditioning at least a portion of the synthesis gas and/or upgrading at least a portion of the Fischer-Tropsch synthesis products. A system for carrying out the method is also provided. | 06-27-2013 |
20140037509 | SUPPLEMENTAL FUEL TO COMBUSTOR OF DUAL FLUIDIZED BED GASIFIER - A method of gasification by introducing a feed material to be subjected to gasification into a dual fluidized bed gasifier comprising a pyrolyzer fluidly connected with a combustor such that a circulation stream comprising a heat transfer material can be continuously circulated between the pyrolyzer, in which the temperature of the circulation stream is reduced, and the combustor, in which the temperature of the circulation stream is increased, wherein the pyrolyzer is operable to convert at least a portion of the feed material into a gasifier product gas comprising hydrogen and carbon monoxide, and wherein the combustor is operable to increase the temperature of the circulation stream via combustion of char introduced thereto with the circulation stream and at least one supplemental fuel. A system for carrying out the method is also provided. | 02-06-2014 |
20140161676 | SEAL POT DESIGN - An apparatus including at least one seal pot having at least one penetration through a surface other than the top of the seal pot, each of the at least one penetrations being configured for introduction, into the at least one seal pot, of solids from a separator upstream of the at least one seal pot; a substantially non-circular cross section; or both at least one penetration through a surface other than the top of the seal pot and a substantially non-circular cross section. | 06-12-2014 |
Patent application number | Description | Published |
20090262012 | RADIOMETER AND TEMPERATURE COMPENSATION SYSTEM - A radiometer for measuring temperature data can include a data reader for reading target data associated with a measurement target and generating temperature data based on the target data. A temperature compensation system can include a radiometer with a data reader and one or more data tags placed proximate corresponding measurement targets. The data tags can contain target data including a target identifier and/or compensation data, among other data. The compensation data can include, for example, a target emissivity. In some embodiments the data reader can include an optical scanning device and/or an RFID reader. | 10-22-2009 |
20110014812 | THERMAL IMAGING DEVICE WITH A BATTERY PACK WITH A SHOCK ABSORBER - A thermal imaging device includes a replaceable battery pack, which may include a shock absorbing and/or seal member. A battery portion of the battery pack includes an electrical contact and a sidewall that contains at least one battery cell, which is electrically coupled to the contact. An attachment mechanism of the battery pack is configured to engage a portion of a housing of the device, such that a portion of the battery pack forms a terminal end of the device, the battery portion is held within the portion of the housing, and the electrical contact of the battery portion is operably connected to the imaging assembly of the device. The attachment mechanism is releasable from engagement with the housing, such that an entirety of the battery pack can be completely separated from the thermal imaging device. | 01-20-2011 |
20110091758 | THERMAL IMAGING DEVICE WITH A BATTERY PACK WITH A SEAL MEMBER MOLDED DIRECTLY THEREON - A thermal imaging device includes a replaceable battery pack, which may include a shock absorbing and/or seal member. A battery portion of the battery pack includes an electrical contact and a sidewall that contains at least one battery cell, which is electrically coupled to the contact. An attachment mechanism of the battery pack is configured to engage a portion of a housing of the device, such that a portion of the battery pack forms a terminal end of the device, the battery portion is held within the portion of the housing, and the electrical contact of the battery portion is operably connected to the imaging assembly of the device. The attachment mechanism is releasable from engagement with the housing, such that an entirety of the battery pack can be completely separated from the thermal imaging device. | 04-21-2011 |
Patent application number | Description | Published |
20100245096 | OPTICAL DATA TRANSFORMATION - Apparatus, systems, and methods may operate to receive interacted energy at an optical calculation device attached to a down hole housing to be deployed in a down hole environment. Further activities may include optically compressing data carried by the interacted energy into at least one orthogonal component, using the optical calculation device, sending a signal associated with the at least one orthogonal component to a remote surface computer, and determining a property of petroleum located in the down hole environment using the remote surface computer, based on the signal. The optical calculation device may comprise a multivariate optical element (MOE). Additional apparatus, systems, and methods are disclosed. | 09-30-2010 |
20100265509 | In situ optical computation fluid analysis system and method - A multivariate optical element (MOE) calculation device is used in an apparatus for determining a property of petroleum in real time flowing in a pipe in petroleum field stream pipes or pipe line. Multiple apparatuses are provided for determining the amount of each of a plurality of properties. An internal reflectance element (IRE) is used to determine the property of the petroleum from a surface of the petroleum flowing in a pipe. A cleaning apparatus is provided to clean the surface of the IRE in the pipe and a turbulence generator is provided in the pipe to insure homogeneity of the petroleum being analyzed prior to analysis. A bellows may be provided the apparatus housing to compensate for pressure differentials between the housing and the flowing petroleum in the pipe. Various embodiments are disclosed. | 10-21-2010 |
20120160018 | MEASUREMENT OF FORMATION ROCK PROPERTIES BY DIFFUSION - Embodiments of the present invention relate to a method to determine formation measurements, the method comprising placing a sample in a reservoir, removing aliquots from the reservoir containing the sample or continuously monitoring the reservoir or headspace as the sample and reservoir equilibrate and analyzing the aliquots or readings sufficient to provide diffusion measurements. | 06-28-2012 |
20130314709 | OPTICAL DATA TRANSFORMATION - Apparatus, systems, and methods may operate to receive interacted energy at an optical calculation device attached to a down hole housing to be deployed in a down hole environment. Further activities may include optically compressing data carried by the interacted energy into at least one orthogonal component, using the optical calculation device, sending a signal associated with the at least one orthogonal component to a remote surface computer, and determining a property of petroleum located in the down hole environment using the remote surface computer, based on the signal. The optical calculation device may comprise a multivariate optical element (MOE). Additional apparatus, systems, and methods are disclosed. | 11-28-2013 |
Patent application number | Description | Published |
20100071633 | Descenting Systems And Methods - Systems and methods for using a scent elimination device to conceal contraband and then training service animals to determine if an ozone-based scent-removal technique has been used to remove scent from contraband are disclosed. The systems and methods comprise providing a plurality of packages. At least one of the plurality of packages containing a predetermined amount of a contraband substance. Further, the systems and methods comprise generating a gaseous stream of descenting material from a portable device. The gaseous stream of descenting material contains ozone. Further, the systems and methods comprise dispersing the gaseous stream of descenting material over the contraband in a concentration sufficient to eliminate the scent. The descented contraband may be placed in an enclosure for transport. Further, the systems and methods comprise introducing a service animal to the plurality of packages. Finally, the systems and methods comprise rewarding the service animal for the successful detection of the at least one of the plurality of packages containing the ozone-based scent remover. | 03-25-2010 |
20120063951 | SYSTEM AND METHOD FOR REDUCING ODORS IN A BLIND - The present invention provides a method and apparatus for controlling a concentration of descenting particles within a temporary structure. The temporary structure comprises a plurality of sidewalls and a roof interconnecting the sidewalls. A plurality of selectively openable and closeable upper windows and lower vents are disposed in the sidewalls. The lower vents are disposed at a location below the upper windows. An ozone generator is disposed within and coupled to the temporary structure to produce descenting particles that are controlled within a hunting zone of the temporary structure to be between about 0.04 and 0.1 ppm. | 03-15-2012 |
20130125944 | SYSTEM AND METHOD FOR REDUCING ODORS IN A BLIND - The present invention provides a method and apparatus for controlling a concentration of descenting particles within a temporary structure. The temporary structure comprises a plurality of sidewalls and a roof interconnecting the sidewalls. A plurality of selectively openable and closeable upper windows and lower vents are disposed in the sidewalls. The lower vents are disposed at a location below the upper windows. An ozone generator is disposed within and coupled to the temporary structure to produce descenting particles that are controlled within a hunting zone of the temporary structure to be between about 0.04 and 0.1 ppm. | 05-23-2013 |
20130171022 | SYSTEM AND METHOD FOR REDUCING ODORS IN A BLIND - The present invention provides a method and apparatus for controlling a concentration of descenting particles within a temporary structure. The temporary structure comprises a plurality of sidewalls and a roof interconnecting the sidewalls. A plurality of selectively openable and closeable upper windows and lower vents are disposed in the sidewalls. The lower vents are disposed at a location below the upper windows. An ozone generator is disposed within and coupled to the temporary structure to produce descenting particles that are controlled within a hunting zone of the temporary structure to be between about 0.04 and 0.1 ppm. | 07-04-2013 |