The present disclosure relates to techniques for extracting heat energy from geothermal briny fluid. A briny fluid can be extracted from a geothermal production well and delivered to a heat exchanger. The heat exchanger can receive the briny fluid and transfer heat energy from the briny fluid to a molten salt. The molten salt can be pumped to a molten salt storage tank that can serve as energy storage. The briny fluid can be returned to a geothermal source via the production well. The briny fluid can remain in a closed-loop system, apart from the molten salt, from extraction through return to the geothermal production well.

The present disclosure relates to techniques for extracting heat energy from geothermal briny fluid. A briny fluid can be extracted from a geothermal production well and delivered to a heat exchanger. The heat exchanger can receive the briny fluid and transfer heat energy from the briny fluid to a molten salt. The molten salt can be pumped to a molten salt storage tank that can serve as energy storage. The briny fluid can be returned to a geothermal source via the production well. The briny fluid can remain in a closed-loop system, apart from the molten salt, from extraction through return to the geothermal production well.

A Hydrostatic Kinetic Energy Recovery System in this present arrangement employs a chain of pressure recovery capsules that are driven down a buried in the ground U shape pipe filled with water. At the present arrangement's depth of 80 feet, water pressure at bottom is 43 PSI which the capsule that includes a one way valve captures at that depth. The capsules are then pulled out via a wheel which houses a number of receiving modules where the captured pressure in the capsules is released through a turbine which is coupled with a generator, thus creating electricity via recovering kinetic energy of column of water.

A Hydrostatic Kinetic Energy Recovery System in this present arrangement employs a chain of pressure recovery capsules that are driven down a buried in the ground U shape pipe filled with water. At the present arrangement's depth of 80 feet, water pressure at bottom is 43 PSI which the capsule that includes a one way valve captures at that depth. The capsules are then pulled out via a wheel which houses a number of receiving modules where the captured pressure in the capsules is released through a turbine which is coupled with a generator, thus creating electricity via recovering kinetic energy of column of water.

A fertilizer gradient energy system includes a membrane module. A membrane module may include a first section and a second section. The first and second sections may be separated by a semipermeable membrane. A load may be connected to the membrane module. The first section may be configured to receive a concentrated fertilizer solution. The second section may be configured to receive a freshwater feed solution. In embodiments, a semipermeable membrane may be configured to facilitate pressure retarded osmosis of the freshwater feed solution from the first section to the second section to increase a fluid pressure in the second section. The semipermeable membrane may include an anion exchange membrane. The membrane module may include a third section. A cation exchange membrane may separate the first and third section. Anion and cation exchange membranes may facilitate reverse electrodialysis. Methods of capturing energy via a membrane module are also disclosed.

A system comprises a production well having an inlet in fluid communication with an underground reservoir, wherein the reservoir is at a first temperature and contains a native aqueous solution, a working fluid withdrawn from the reservoir into the inlet and through the production well. The working fluid comprises a non-water component and an aqueous component comprising a portion of the aqueous solution. The system further comprises a separation apparatus in communication with the production well configured to separate the aqueous component from the working fluid to provide a dewatered working fluid, wherein the aqueous component is from more than 0 wt. % to no more than a specified threshold of the dewatered working fluid. The system also includes an energy recovery system that comprises an expansion device through which the dewatered working fluid passes and produces work energy and a generator that converts the work energy to electricity.

A system comprises a production well having an inlet in fluid communication with an underground reservoir, wherein the reservoir is at a first temperature and contains a native aqueous solution, a working fluid withdrawn from the reservoir into the inlet and through the production well. The working fluid comprises a non-water component and an aqueous component comprising a portion of the aqueous solution. The system further comprises a separation apparatus in communication with the production well configured to separate the aqueous component from the working fluid to provide a dewatered working fluid, wherein the aqueous component is from more than 0 wt. % to no more than a specified threshold of the dewatered working fluid. The system also includes an energy recovery system that comprises an expansion device through which the dewatered working fluid passes and produces work energy and a generator that converts the work energy to electricity.

Embodiments of systems and methods for generating power in the vicinity of a drilling rig are disclosed. During a drilling operation, heat generated by drilling fluid flowing from a borehole, exhaust from an engine, and/or fluid from an engine's water (or other fluid) jacket, for example, may be utilized by corresponding heat exchangers to facilitate heat transfer to a working fluid. The heated working fluid may cause an ORC unit to generate electrical power.

Thermal energy is extracted from geological formations using a heat harvester. In some embodiments, the heat harvester is a once-through, closed loop, underground heat harvester created by directionally drilling through hot rock. The extracted thermal energy can be converted or transformed to other forms of energy.

Thermal energy is extracted from geological formations using a heat harvester. In some embodiments, the heat harvester is a once-through, closed loop, underground heat harvester created by directionally drilling through hot rock. The extracted thermal energy can be converted or transformed to other forms of energy.