A multivessel system is provided for drilling an ultra-deep borehole into the Earth's lithosphere. The system includes a plurality of gate valves, a first pressure vessel configured with a first vessel elevator that engages and holds a train section as the first vessel elevator moves in the first pressure vessel along a portion of a length of a drill train channel; a second pressure vessel configured with a second vessel elevator that engages and holds the train section as the second vessel elevator moves in the second pressure vessel along another portion of the length of the drill train channel; a third pressure vessel configured with a smooth cylinder bore and a burn gas ejection piston configured to hold and connect the train section to the drill train; an input-output separator configured to segregate an exhaust waste gas up-flowing from the borehole from a gas being supplied into the borehole; and a drill train clamp configured to engage and hold a drill train in a borehole.

A multivessel system is provided for drilling an ultra-deep borehole into the Earth's lithosphere. The system includes a plurality of gate valves, a first pressure vessel configured with a first vessel elevator that engages and holds a train section as the first vessel elevator moves in the first pressure vessel along a portion of a length of a drill train channel; a second pressure vessel configured with a second vessel elevator that engages and holds the train section as the second vessel elevator moves in the second pressure vessel along another portion of the length of the drill train channel; a third pressure vessel configured with a smooth cylinder bore and a burn gas ejection piston configured to hold and connect the train section to the drill train; an input-output separator configured to segregate an exhaust waste gas up-flowing from the borehole from a gas being supplied into the borehole; and a drill train clamp configured to engage and hold a drill train in a borehole.

A system and method of harvesting geothermal energy in a subterranean formation includes providing an injection wellbore that extends into the subterranean formation, positioning a plurality of selectively opening sleeves in the injection wellbore spaced apart the subterranean formation, providing at least one producing wellbore that extends into the subterranean formation in a predetermined location proximate to the injection wellbore, and fracturing the subterranean formation in a plurality of locations proximate to the plurality of selectively opening sleeves to enhance a fluid pathway between the injection wellbore and the at least one producing wellbore. Fluid is injected down the injection wellbore at a first temperature, and the fluid is produced from the at least one producing wellbore at a second temperature higher than said first temperature.

A system and method for harnessing geothermal energy using fracturing of hot rock. The system has at least a first well and a second well. The method involves introducing an alkali metal downhole in a first well. A solution is also introduced into the first well. The solution produces an exothermic reaction with the alkali metal. The gas and heat fracture the hot rock producing fractures. The fractures fluidly connects the first well to the second well. A solution, such as water, can be pumped through the first well, through the fractures, and into the second well. The hot rock passes geothermal energy to the water which can then be utilized.

A system and method for harnessing geothermal energy using fracturing of hot rock. The system has at least a first well and a second well. The method involves introducing an alkali metal downhole in a first well. A solution is also introduced into the first well. The solution produces an exothermic reaction with the alkali metal. The gas and heat fracture the hot rock producing fractures. The fractures fluidly connects the first well to the second well. A solution, such as water, can be pumped through the first well, through the fractures, and into the second well. The hot rock passes geothermal energy to the water which can then be utilized.

A system comprises an injection well for accessing reservoir at a first temperature; a production well in fluid communication with the reservoir; a working-fluid supply system providing a non-water based working fluid to the injection well at a second temperature lower than the first temperature, wherein exposure of the working fluid to the first temperature heats the working fluid to a third temperature and at least a portion of the working fluid at the third temperature is produced as a production fluid; and an energy recovery system that converts energy contained in the production fluid to electricity or heat, wherein the energy recovery system includes a waste heat recovery apparatus that recovers waste heat and uses it to heat the production fluid to a fourth temperature that is higher than the third temperature, wherein the waste heat is recovered from equipment of or a process stream.

A system comprises an injection well for accessing reservoir at a first temperature; a production well in fluid communication with the reservoir; a working-fluid supply system providing a non-water based working fluid to the injection well at a second temperature lower than the first temperature, wherein exposure of the working fluid to the first temperature heats the working fluid to a third temperature and at least a portion of the working fluid at the third temperature is produced as a production fluid; and an energy recovery system that converts energy contained in the production fluid to electricity or heat, wherein the energy recovery system includes a waste heat recovery apparatus that recovers waste heat and uses it to heat the production fluid to a fourth temperature that is higher than the third temperature, wherein the waste heat is recovered from equipment of or a process stream.

The invention relates to a method for sizing a geothermal well for the thermal regulation of a building, including the steps of: 51: Modelling a geothermal potential of a zone of interest including a subsoil zone comprised within a given perimeter around the building; S2: Estimating the thermal requirements of the building; S3: Generating models of geothermal installations according to the results of 51 and S2, a model of a geothermal installation including one or more geothermal solutions configured to meet the requirements estimated in step S2 according to the zone of interest modelled in step 51; S4: Applying a selection criterion which is configured to determine a preferred model.

The invention relates to a method for sizing a geothermal well for the thermal regulation of a building, including the steps of: 51: Modelling a geothermal potential of a zone of interest including a subsoil zone comprised within a given perimeter around the building; S2: Estimating the thermal requirements of the building; S3: Generating models of geothermal installations according to the results of 51 and S2, a model of a geothermal installation including one or more geothermal solutions configured to meet the requirements estimated in step S2 according to the zone of interest modelled in step 51; S4: Applying a selection criterion which is configured to determine a preferred model.

Example heating and cooling systems for edge data centers are disclosed herein. A system disclosed herein includes a subterranean vault to be disposed at least partially below ground level an of environment, an edge data center in the subterranean vault, and a geothermal heat pump system to regulate a temperature of ambient air in the subterranean vault.