Abstract: A method and apparatus for implementing a thermodynamic cycle which may be used to convert low temperature heat to electric power.

Abstract: A method and apparatus for implementing a thermodynamic cycle, which includes heating and preferably partially evaporating a multicomponent liquid working stream with heat released from the partial condensation of a returning spent stream. The preferably partially evaporated working stream is then completely evaporated with heat transferred from an external heat source, which is preferably a geothermal heat source. The evaporated stream is expanded to produce the spent stream, which, in turn, is condensed to produce the multicomponent liquid working stream.

Abstract: A method and apparatus for implementing a thermodynamic cycle, which includes the use of a composite stream, having a higher content of a high-boiling component than a working stream, to provide heat needed to partially evaporate the working stream. After being partially evaporated, the working stream is evaporated completely with heat provided by returning gaseous working streams and heat from an auxiliary steam cycle. After being superheated, the working stream is expanded in a turbine. Thereafter, the expanded stream is separated into a spent stream and a withdrawal stream. The withdrawal stream is combined with a lean stream to produce the composite stream. The composite stream partially evaporates the working stream and preheats the working stream and the lean stream. A first portion of the composite stream is fed into a distillation tower. A liquid stream flowing from the distillation tower forms the lean stream that is combined with the withdrawal stream.

Abstract: A method and apparatus for implementing a thermodynamic cycle with preheating, involves expanding a gaseous working fluid to a medium pressure to transform its energy into usable form. The expanded gaseous working fluid is split into two different streams. One stream is further expanded to a spent low pressure level to produce further usable energy. This stream is then condensed. The other of the two streams is used to preheat the condensed stream and is mixed with the condensed stream at a point upstream of the point of preheating. This decreases the irreversibilities in the preheating process and enables greater efficiencies to be achieved.

Abstract: A method and apparatus for implementing a thermodynamic cycle, which includes the use of a composite stream, having a higher content of a high-boiling component than a working stream, to provide heat needed to evaporate the working stream. After being superheated, the working stream is expanded in a turbine. Thereafter, the expanded stream is separated into a spent stream and a withdrawal stream. The withdrawal stream is combined with a lean stream to produce a composite stream. The composite stream evaporates the working stream and preheats the working stream and the lean stream. The composite stream is then expanded to a reduced pressure. A first portion of this composite stream is fed into a gravity separator. The liquid stream flowing from the gravity separator forms a portion of the lean stream that is combined with the withdrawal stream. The vapor stream flowing from the separator combines with a second portion of the composite stream in a scrubber.

Abstract: A method and apparatus for implementing a thermodynamic cycle with intercooling, includes a condensing subsystem, a boiler, and a turbine. The boiler may include a preheater, an evaporator, and a superheater. After initial expansion in the turbine, the fluid may be diverted to a reheater to increase the temperature available for superheating. After return to the turbine and additional expansion, the fluid may be withdrawn from the turbine and cooled in an intercooler. Thereafter the fluid is returned to the turbine for additional expansion. The cooling of the turbine gas may provide additional heat for evaporation. Intercooling may provide compensation for the heat used in reheating and may provide recuperation of available heat which would otherwise remain unused following final turbine expansion.

Abstract: A method and apparatus for implementing a thermodynamic cycle involves utilizing partial distillation of a multi-component working fluid stream. At least one main enriched solution is produced which is relatively enriched with respect to the lower boiling temperature component, together with at least one lean solution which is relatively impoverished with the respect of lower boiling temperature component. The main working fluid is expanded to a low pressure level to convert energy to a usable form. This spent low pressure level working fluid is condensed by dissolving with cooling in the lean solution to regenerate an initial working fluid for reuse. A portion of the impoverished fraction may be injected into the charged gaseous main working fluid in order to obtain added work and to increase system efficiency by decreasing the temperature of the output fluid flow when the fluid flow would otherwise have been superheated.

Abstract: A method of generating energy in which working fluid fractions of differing compositions are generated, are subjected to heating in a first evaporator stage, are combined, the combined stream is then evaporated and is expanded to convert its energy into usable form. Thereafter the combined stream is processed to regenerate the differing working fluid fractions for reuse.

Abstract: A method of generating energy which comprises utilizing relatively lower temperature available heat to effect partial distillation of at least portion of a multicomponent working fluid stream at an intermediate pressure to generate working fluid fractions of differing compositions. The fractions are used to produce at least one main rich solution which is relatively enriched with respect to the lower boiling component, and to produce at least one lean solution which is relatively improverished with respect to the lower boiling component. The pressure of the main rich solution is increased whereafter it is evaporated to produce a charged gaseous main working fluid. The main working fluid is expanded to a low pressure level to release energy. The spent low pressure level working fluid is condensed in a main absorption stage by dissolving with cooling in the lean solution to regenerate an initial working fluid for reuse.

Abstract: A gas lift method for lifting a well fluid from a well, the method comprising feeding a liquid lifting medium into a first well conduit of the well to maintain a liquid column of liquid lifting medium in the first well conduit to provide a significant liquid column pressure at the downhole region of the well for lifting medium to pass into a second well conduit to mix with well fluid therein and cause lifting of well fluid in the second well conduit.

Abstract: A method of selectively blocking high permeability flow channels in an underground hydrocarbon material bearing formation having flow channels of high permeability and having flow channels of lesser permeability.

Abstract: A method of optimizing, within limits imposed by a heating medium from the surface of an ocean and a cooling medium from an ocean depth, the energy supply capability of a gaseous working fluid which is expanded from a charged high pressure level to a spent low pressure level to provide available energy, the method comprising expanding the gaseous working fluid to a spent low pressure level where the condensation temperature of the working fluid is below the minimum temperature of the cold water, and regenerating the spent working fluid by, in at least one regeneration stage, absorbing the working fluid being regenerated in an absorption stage by dissolving it in a solvent solution while cooling with the cold water, the solvent solution comprising a solvent having an initial working fluid concentration which is sufficient to provide a solution having a boiling point, after dissolving the working fluid being regenerated, which is above the minimum temperature of the cold water to permit effective absorption of

Abstract: A method of heating a hydrocarbon material contained in a recovery zone in an underground hydrocarbon material-bearing formation to reduce the viscosity thereof for facilitating recovery of the hydrocarbon material, in which a gaseous penetration medium comprising a gaseous working fluid and a carrier gas, is fed into the formation at a penetration pressure sufficient for penetration of the recovery zone, the working fluid being a water soluble gas which generates heat of solution upon absorption in an aqueous medium, and in which the partial pressure of the working fluid in relation to the penetration pressure and the temperature prevailing in the recovery zone is controlled to inhibit working fluid condensation but to provide for absorption of working fluid by water present in the formation to release heat for heating the hydrocarbon material in the recovery zone.

Abstract: A pipeline capsule transportation apparatus and method for transporting capsules in a continuous linked train, including an elongated pipeline having a plurality of sets of upstream and downstream pipeline locations, a plurality of energy transfer stations downstream of the various downstream pipeline locations, each transfer station comprising an elongated enclosure which surrounds a length of pipeline and is in fluid communication with the length of pipeline, the enclosure having an inner diameter larger than that of the pipeline, station pumps for withdrawing fluid from a downstream location of each station and pumping the fluid into an upstream location of each station to provide downstream fluid flow along the enclosure of each station for propelling capsules passing through the length of pipeline in such enclosure, and control pumps for controlling the velocity of fluids between each set of upstream and downstream pipeline locations during use for the pressure to be less at each upstream pipline locatio

Abstract: A pipeline capsule transportation system and apparatus for transporting a continuous link of capsules, comprising a first elongated pipeline and a second elongated pipeline along which continuous links of capsules are to be transported, a loading station for loading capsules, and an unloading station for unloading capsules, the loading station comprising at least one handling zone, an inclined discharge conduit for displacing capsules from the handling zone to the first pipeline, a capsule coupler for coupling capsules entering the first pipeline to a trailing end of a continuous link of capsules moving along the first pipeline during use, decoupling apparatus for decoupling trains of capsules from a leading end of a continuous link of capsules moving in the second pipeline, a downhill station entrance ramp for diverting decoupled capsules to the handling zone, and a brake for bringing trains of capsules to rest in the handling zone.

Abstract: A magnet, a support arm for connecting the magnet to a load, and an adjusting mechanism for adjusting a magnitude of the field of the magnet in relation to variations in the load and method are disclosed.