Method for installing a geothermal system, comprising: arranging a drilling equipment, including a support structure and a terminal module, mounted on the support structure; by means of the drilling equipment, drilling the soil in succession along a substantially vertical first tract, a substantially horizontal second tract and a substantially vertical third tract, the first, second and third tracts forming a substantially U-shaped well, the first tract having a surface inlet, where the drilling is started, the third tract having a surface outlet, where the drilling is finished, the well crossing a geothermal zone; arranging a casing in the well, so that the casing extends between the inlet of the first tract and the outlet of the third tract; arranging a heat utilization system, associated with an axial end of the casing; arranging a hydraulic system configured to cause a heat transfer fluid to circulate in the casing, so that the heat transfer fluid will absorb heat from the geothermal formation and will release it at the heat utilization system.

A heat exchange circuit for a geothermal plant comprising a well excavated in the rock, a casing arranged inside the well, integral with it and comprising at least a first perforated section extending along a first portion of the well and at least a second perforated section extending along a second portion of the well, the perforated sections allowing the exit and the entry of a flow of geothermal fluid contained in an aquifer, an internal duct, located inside the casing in which a heat transfer fluid flows, wherein the well, the casing and the internal duct being arranged as a substantially closed ring, except for at least one surface interruption, at least one heat-exchange section at the bottom of the well between the first portion and the second portion of the well within which the geothermal fluid transfers heat to the heat transfer fluid.

A heat exchange circuit for a geothermal plant comprising a well excavated in the rock, a casing arranged inside the well, integral with it and comprising at least a first perforated section extending along a first portion of the well and at least a second perforated section extending along a second portion of the well, the perforated sections allowing the exit and the entry of a flow of geothermal fluid contained in an aquifer, an internal duct, located inside the casing in which a heat transfer fluid flows, wherein the well, the casing and the internal duct being arranged as a substantially closed ring, except for at least one surface interruption, at least one heat-exchange section at the bottom of the well between the first portion and the second portion of the well within which the geothermal fluid transfers heat to the heat transfer fluid.

System, method, and apparatus for harnessing geothermal power from superhot geothermal fluid (SHGF) and magma reservoirs. An exemplary embodiment is directed to a cased wellbore includes a well casing suspended within a borehole that extends between a surface and an underground reservoir of magma and a boiler casing housed within the well casing and extending between the surface and the underground reservoir of magma. The boiler casing has a first end submerged within the underground reservoir of magma and a terminal end opposite to the first end. The cased wellbore also includes a fluid conduit housed within the boiler casing and configured to deliver a liquid-phase fluid to the terminal end of the boiler casing. A temperature and a pressure at the terminal end of the boiler casing converts the liquid-phase fluid into a gas-phase fluid that travels through the boiler casing towards the surface. The cased wellbore also includes a well head connected to the first end of the boiler casing.

System, method, and apparatus for harnessing geothermal power from superhot geothermal fluid (SHGF) and magma reservoirs. An exemplary embodiment is directed to a cased wellbore includes a well casing suspended within a borehole that extends between a surface and an underground reservoir of magma and a boiler casing housed within the well casing and extending between the surface and the underground reservoir of magma. The boiler casing has a first end submerged within the underground reservoir of magma and a terminal end opposite to the first end. The cased wellbore also includes a fluid conduit housed within the boiler casing and configured to deliver a liquid-phase fluid to the terminal end of the boiler casing. A temperature and a pressure at the terminal end of the boiler casing converts the liquid-phase fluid into a gas-phase fluid that travels through the boiler casing towards the surface. The cased wellbore also includes a well head connected to the first end of the boiler casing.

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 multivessel system is provided for installing a production train in an ultra-deep borehole into the Earth's lithosphere. The system includes a plurality of gate valves and a plurality of pressure vessels, including a first pressure vessel having a first vessel elevator configured to engage and hold a production train section as the first vessel elevator moves in the first pressure vessel along a portion of a length of a train channel, a second pressure vessel having a second vessel elevator configured to engage and hold the production train section as the second vessel elevator moves in the second pressure vessel along another portion of the length of the train channel, and a third pressure vessel, with all three pressure vessels being configured to be water cooled. The system includes a train clamp configured to engage and hold the production train in the borehole. Each of the first vessel elevator and the second vessel elevator includes a clamp configured to engage and hold the train section as the respective first vessel elevator or the second vessel elevator moves along the train channel.

A multivessel system is provided for installing a production train in an ultra-deep borehole into the Earth's lithosphere. The system includes a plurality of gate valves and a plurality of pressure vessels, including a first pressure vessel having a first vessel elevator configured to engage and hold a production train section as the first vessel elevator moves in the first pressure vessel along a portion of a length of a train channel, a second pressure vessel having a second vessel elevator configured to engage and hold the production train section as the second vessel elevator moves in the second pressure vessel along another portion of the length of the train channel, and a third pressure vessel, with all three pressure vessels being configured to be water cooled. The system includes a train clamp configured to engage and hold the production train in the borehole. Each of the first vessel elevator and the second vessel elevator includes a clamp configured to engage and hold the train section as the respective first vessel elevator or the second vessel elevator moves along the train channel.

Systems and methods for producing energy from a geothermal formation. A heat exchanger can be disposed within a well to absorb heat from a geothermal formation. The heat exchanger can be supported within the well using a high thermal conductivity material. The heat exchanger is connected to an organic Rankine cycle engine including a secondary heat exchanger and a turbine. The primary and secondary heat transfer fluids are chosen to maximize efficiency of the organic Rankine cycle.