Abstract: A feed beater (114) for a single-rotor, axial-flow combine (100) that comprises a cylinder (200) having a first end portion and a second end portion; first blades (202) fixed to the first end portion of the cylinder (200) and disposed at a first angle (alpha) with respect to a rotational axis (300) of the cylinder (200); second blades (204) fixed to the second end portion of the cylinder (200) and disposed at a second angle (beta) with respect to the rotational axis (300) of the cylinder (200); the first blades (202) spiral in a first direction over a first longitudinal extent of the cylinder (200); and the second blades (204) spiral in a second direction over a second longitudinal extent of the cylinder (200), wherein the second direction is opposite to the first direction, and further wherein the first longitudinal extent is greater than the second longitudinal extent.

Abstract: An axial-flow turbine assembly that includes one or more features for enhancing the efficiency of the turbine's operation. In one embodiment, the turbine assembly includes a turbine rotor having blades that adjust their pitch angle in direct response to working fluid pressure on the blades themselves or other part(s) of the rotor. In other embodiments, the turbine assembly is deployable in an application, such as an oscillating water column system, in which the flow of working fluid varies over time, for example, as pressure driving the flow changes. In a first of these embodiments, the turbine assembly includes a valve that allows the pressure to build so that the flow is optimized for the turbine's operating parameters. In a second of these embodiments, one or more variable-admission nozzle and shutter assemblies are provided to control the flow through the turbine to optimize the flow relative to the turbine's operating parameters.

Abstract: In a geothermal power system that includes a turbine generator, a down-hole heat exchanger, and a turbine pump assembly, various arrangements for the turbine pump assembly are described. Those arrangements address considerations related to the design of the down-hole turbine pump. In such a system, the turbine generator receives a high pressure working fluid from the down-hole system to drive a generator. The turbine generator is in fluid communication with the down-hole heat exchanger and with the turbine portion of a removably disposed down-hole turbine pump assembly. The pump portion of the down-hole turbine pump assembly is in fluid communication with the down-hole heat exchanger and a source of geothermal fluid.

Abstract: An axial-flow turbine assembly that includes one or more features for enhancing the efficiency of the turbine's operation. In one embodiment, the turbine assembly includes a turbine rotor having blades that adjust their pitch angle in direct response to working fluid pressure on the blades themselves or other part(s) of the rotor. In other embodiments, the turbine assembly is deployable in an application, such as an oscillating water column system, in which the flow of working fluid varies over time, for example, as pressure driving the flow changes. In a first of these embodiments, the turbine assembly includes a valve that allows the pressure to build so that the flow is optimized for the turbine's operating parameters. In a second of these embodiments, one or more variable-admission nozzle and shutter assemblies are provided to control the flow through the turbine to optimize the flow relative to the turbine's operating parameters.

Abstract: A turbine-generator device for use in electricity generation using heat from industrial processes, renewable energy sources and other sources. The generator may be cooled by introducing into the gap between the rotor and stator liquid that is vaporized or atomized prior to introduction, which liquid is condensed from gases exhausted from the turbine. The turbine has a universal design and so may be relatively easily modified for use in connection with generators having a rated power output in the range of 50 KW to 5 MW. Such modifications are achieved, in part, through use of a modular turbine cartridge built up of discrete rotor and stator plates sized for the desired application with turbine brush seals chosen to accommodate radial rotor movements from the supported generator. The cartridge may be installed and removed from the turbine relatively easily for maintenance or rebuilding. The rotor housing is designed to be relatively easily machined to dimensions that meet desired operating parameters.

Abstract: A turbine that allows for the conversion of the kinetic energy of waterway to mechanical power for use in an energy accepting apparatus is described. The turbine has complimentary components that improve the power efficiency of the turbine. The turbine may include a blade shroud and a plurality of blades that are connected to the blade shroud. On the external surface of the blade shroud, a drive mechanism and/or a brake mechanism may be disposed. An inlet nozzle and outlet diffuser may be used in combination with the turbine. The turbine may be useful in a number of settings, including, but not limited to, streams, rivers, dams, ocean currents, or tidal areas that have continuous or semi-continuous water flow rates and windy environments.

Abstract: An embodiment provides a method for managing a hydrocarbon asset. The method includes creating an interactive community of agents, wherein each agent comprises code and functional data structures configured to direct a processor to access resource on a network. At least one of the agents is configured to be a workflow agent, wherein the work-flow agent is configured to pursue a plan to accomplish a goal. The work-flow agent is provided with sensors to determine environmental conditions. The workflow agent is provided with the ability to communicate with other intelligent agents. The workflow agent is configured to select the plan based, at least in part, on information obtained from the sensors.

Abstract: An axial-flow turbine assembly that includes one or more features for enhancing the efficiency of the turbine's operation. In one embodiment, the turbine assembly includes a turbine rotor having blades that adjust their pitch angle in direct response to working fluid pressure on the blades themselves or other part(s) of the rotor. In other embodiments, the turbine assembly is deployable in an application, such as an oscillating water column system, in which the flow of working fluid varies over time, for example, as pressure driving the flow changes. In a first of these embodiments, the turbine assembly includes a valve that allows the pressure to build so that the flow is optimized for the turbine's operating parameters. In a second of these embodiments, one or more variable-admission nozzle and shutter assemblies are provided to control the flow through the turbine to optimize the flow relative to the turbine's operating parameters.

Abstract: A system for installing and extracting a flowing water turbine below the surface of the water includes a flow inducer assembly for improving the conversation of the kinetic energy of a waterway to mechanical energy. The flow inducer assembly includes a nozzle that may be shaped as a cowling and a outlet diffuser. The system may be useful in a number of settings, including, but not limited to, streams, rivers, dams, ocean currents, or tidal areas that have continuous or semi-continuous water flow rates and windy environments.

Abstract: A hydropower generating turbine having an impeller housing disposed to receive water, at least one impeller disposed within the impeller housing, at least one adjustable duct pivotally connected to the impeller housing, and, where the duct has a plurality of duct leafs, wherein the duct leafs articulate and cause the duct to converge and diverge for selectively disposing a fluid about the impeller. The ducts may be inflow or outflow ducts, and the turbine may react to a change in the fluid and alter the shape of the impeller. Further, the turbine may have an automated controller where variable change in the flow is detected by a sensor and transmitted to the automated controller to cause a directional shift in the multidirectional turbine.

Abstract: Hydrogen gas compression systems that each include a multistage centrifugal compressor in which each stage has an inlet-to-outlet pressure rise ratio of about 1.20 or greater. In one embodiment, the multistage compressor includes six high-speed centrifugal compressors driven at a speed of about 60,000 rpm. The compressor has an output of more than 200,000 kg/day at a pressure of more than 1,000 psig. The compressors for the compression stages are distributed on both sides of a common gear-box, which has gearing that allows axial thrusts from the compressors to be handled effectively. Each stage's compressor has a unique impeller, which is secured to a support shaft using a tension-rod-based attachment system. In another embodiment, the multistage compressor is driven by a combustion turbine and one or more intercoolers are provided between compression stages. Each intercooler is cooled by coolant from an absorption chiller utilizing exhaust gas from the combustion turbine.

Abstract: A preferred embodiment includes a system for power generation through movement of fluid having a variety of configurations and implementations. One preferred embodiment includes a system for power generation through movement of fluid includes a power generating cell with a generally cylindrical housing a ring for rotating disposed in said housing, one or more impellers fixedly coupled to said ring, and a generator operably coupled to said ring for receiving energy from the one or more impellers in which fluid is disposed about one or more impellers for creating energy.

Abstract: The present invention provides methods for treating or reducing neurologic disorders.

Abstract: A clamp for connecting a pair of orthogonally disposed pipes. The clamp may comprise a pair of identical clamp halves or brackets, or a pair of mirror-image clamp halves or brackets, each bracket having a centrally located plate portion having one or more apertures, an upper surface, a lower surface and spaced apart ends, each of the ends carrying a curved jaw designed to conform to cylindrical outer surfaces of the pipes. The lower surfaces of the plate portions of the pair of clamp brackets are disposed in confronting relationship with their apertures in alignment, the pair of brackets being coupled with one or more fasteners passing through the aligned apertures. The end jaws of one of the brackets are in opposed relationship with the corresponding end jaws of the other of the brackets, wherein the end jaws of the coupled brackets define a pair of generally cylindrical pipe gripping surfaces each having a longitudinal central axis.

Abstract: A system for installing and extracting a flowing water turbine below the surface of the water includes a flow inducer assembly for improving the conversation of the kinetic energy of a waterway to mechanical energy. The flow inducer assembly includes a nozzle that may be shaped as a cowling and a outlet diffuser. The system may be useful in a number of settings, including, but not limited to, streams, rivers, dams, ocean currents, or tidal areas that have continuous or semi-continuous water flow rates and windy environments.

Abstract: A turbine that allows for the conversion of the kinetic energy of waterway to mechanical power for use in an energy accepting apparatus is described. The turbine has complimentary components that improve the power efficiency of the turbine. The turbine may include a blade shroud and a plurality of blades that are connected to the blade shroud. On the external surface of the blade shroud, a drive mechanism and/or a brake mechanism may be disposed. An inlet nozzle and outlet diffuser may be used in combination with the turbine. The turbine may be useful in a number of settings, including, but not limited to, streams, rivers, dams, ocean currents, or tidal areas that have continuous or semi-continuous water flow rates and windy environments.

Abstract: A harvesting machine including a frame, a plurality of ground engaging wheels, at least one grain separating section, a plurality of cross augers and a grain moving device. The plurality of ground engaging wheels support the frame. The at least one grain separating section is supported by the frame. The plurality of cross augers are positioned to receive grain from the at least one grain separating section. The plurality of cross augers each have an end. The grain moving device is associated with each of the plurality of cross augers proximate to the end of the plurality of cross augers.

Abstract: The invention concerns a harvested crop processing unit with a rotor, a rotor housing enclosing the rotor, a cover element of the rotor housing, and a first group of helical guide rails that can be moved relative to the cover element between an operating position in which they are located underneath the cover element in engagement with harvested crop and a non-operating position in which they are located above the cover element. The invention proposes that a second group of helical guide rails be provided that can be moved alternately with the first group of helical guide rails relative to the cover element between an operating position in which they are located underneath the cover element in engagement with harvested crop and a non-operating position in which they are located above the cover element, and that are provided with an inclination that differs from the inclination of the guide rail of the first group.

Abstract: A distributed architecture for driving various electro-optic reflective display devices (620) is disclosed. Analog processors (6-15) are positioned in close proximity to the electro-optic reflective segments (650) being driven while digital processing functions are performed at a remote location. The analog and digital processors communicate via a bus (640). Various bus types and architectures for coupling the analog and digital processors are disclosed. The distributed architecture is particularly useful in electrochromic displays where the inherent properties of the display require analog sensing of each segment.

Abstract: A harvesting machine including a frame, a plurality of ground engaging wheels, at least one grain separating section, a plurality of cross augers and a grain moving device. The plurality of ground engaging wheels support the frame. The at least one grain separating section is supported by the frame. The plurality of cross augers are positioned to receive grain from the at least one grain separating section. The plurality of cross augers each have an end. The grain moving device is associated with each of the plurality of cross augers proximate to the end of the plurality of cross augers.