The technical outcome of the proposed geothermal energy device is to increase its efficiency (CE), to simplify and cheapen the construction.

The geothermal energy device contains downstream and upstream pipes, which are filled with fluid thermal agent and placed in the borehole; they are connected to each other with a heat exchanger in the depth of the borehole. The downstream pipe is equipped with several mechanical non-return valves; on the same pipe there is also installed a down pushing pump of the thermal agent (e.g. isobutane). The end of the upstream pipe on the ground surface is directed towards the condensation type steam turbine, equipped with the controlled (e.g. electromagnetic) valve, and turned towards the mentioned turbine by the Laval nozzle. The energy device additionally contains the device of the frequency/duration control to lock and unlock the mentioned controlled valve.

The technical outcome of the proposed geothermal energy device is to increase its efficiency (CE), to simplify and cheapen the construction.

The geothermal energy device contains downstream and upstream pipes, which are filled with fluid thermal agent and placed in the borehole; they are connected to each other with a heat exchanger in the depth of the borehole. The downstream pipe is equipped with several mechanical non-return valves; on the same pipe there is also installed a down pushing pump of the thermal agent (e.g. isobutane). The end of the upstream pipe on the ground surface is directed towards the condensation type steam turbine, equipped with the controlled (e.g. electromagnetic) valve, and turned towards the mentioned turbine by the Laval nozzle. The energy device additionally contains the device of the frequency/duration control to lock and unlock the mentioned controlled valve.

The invention relates to a commercially viable modular ceramic oxygen transport membrane system for utilizing heat generated in reactively-driven oxygen transport membrane tubes to generate steam, heat process fluid and/or provide energy to carry out endothermic chemical reactions. The system provides for improved thermal coupling of oxygen transport membrane tubes to steam generation tubes or process heater tubes or reactor tubes for efficient and effective radiant heat transfer.

The invention relates to a commercially viable modular ceramic oxygen transport membrane system for utilizing heat generated in reactively-driven oxygen transport membrane tubes to generate steam, heat process fluid and/or provide energy to carry out endothermic chemical reactions. The system provides for improved thermal coupling of oxygen transport membrane tubes to steam generation tubes or process heater tubes or reactor tubes for efficient and effective radiant heat transfer.

A heat exchanger (10) is disclosed for providing heat exchange between fluids (24, 25), such as in a solar power plant (1), wherein said heat exchanger (10) comprises a first pipe connector (13) and a second pipe connector (14), and a pipe bundle (17) extending between the first and second pipe connectors (13, 14), wherein said pipes (17a-17n) of the pipe bundle (17) are configured to guide a second fluid (25), wherein said pipe bundle (17) is connected to the first and second pipe connectors (13, 14) at pipe connection points (16) so the inside of the pipes (17a-17n) of the pipe bundle (17) is in fluid communication with the cavities (15) of the first and second pipe connector (13, 14), and wherein pipes (17a-17n) of the pipe bundle (17) are arranged next to each other and extend together between the pipe connectors (13, 14) in a meandering manner providing a plurality of crests (20a, 20b) on the pipes (17a-17n) between the pipe connectors (13, 14), and so that crests (20) of pipes (17a-17n) of the pipe bundle (17) are arranged to extend into recesses (21) provided by one or more crests (20) on other pipes (17a-17n) of the pipe bundle (17).

A heat exchanger (10) is disclosed for providing heat exchange between fluids (24, 25), such as in a solar power plant (1), wherein said heat exchanger (10) comprises a first pipe connector (13) and a second pipe connector (14), and a pipe bundle (17) extending between the first and second pipe connectors (13, 14), wherein said pipes (17a-17n) of the pipe bundle (17) are configured to guide a second fluid (25), wherein said pipe bundle (17) is connected to the first and second pipe connectors (13, 14) at pipe connection points (16) so the inside of the pipes (17a-17n) of the pipe bundle (17) is in fluid communication with the cavities (15) of the first and second pipe connector (13, 14), and wherein pipes (17a-17n) of the pipe bundle (17) are arranged next to each other and extend together between the pipe connectors (13, 14) in a meandering manner providing a plurality of crests (20a, 20b) on the pipes (17a-17n) between the pipe connectors (13, 14), and so that crests (20) of pipes (17a-17n) of the pipe bundle (17) are arranged to extend into recesses (21) provided by one or more crests (20) on other pipes (17a-17n) of the pipe bundle (17).

A method of connecting a heat exchanger, which is used primarily in oil and gas operations to heat tanks of liquids, such as drilling mud, water, heavy oil or other such fluids from freezing or becoming too viscous to pump, to a tank.

Methods and systems for generating power (and optionally heat) from a high value heat source using a plurality of circulating loops comprising a primary heat transfer loop, several power cycle loops and an intermediate heat transfer loop that transfers heat from the high-temperature heat transfer loop to the several power cycle loops. The intermediate heat transfer loop is arranged to eliminate to the extent practical the shell and tube heat exchangers especially those heat exchangers that have a very large pressure difference between the tube side and shell side, to eliminate shell and tube, plate type, double pipe and similar heat exchangers that transfer heat directly from the primary heat transfer loop to the several power cycle loops with very high differential pressures and to maximize the use of heat transfer coils similar in design as are used in a heat recovery steam generator commonly used to transfer heat from gas turbine flue gas to steam or other power cycle fluids as part of a combined cycle power plant.

A heat exchanger (10) to provide heat exchange between fluids (24, 25), such as in a solar power plant (1), may include a first and second pipe connectors (13, 14), and a pipe bundle (17) extending between the first and second pipe connectors, with pipes (17a-17n) of the pipe bundle configured to guide a second fluid (25). The pipe bundle may be connected to the first and second pipe connectors at pipe connection points (16) so the inside of the pipes (17a-17n) is in fluid communication with cavities (15) of those connectors. The pipes may be arranged adjacent each other and extending together between the pipe connectors in a meandering manner providing a plurality of crests (20a, 20b) on the pipes between the pipe connectors, so that crests of the pipes are arranged to extend into recesses provided by one or more crests on other pipes of the pipe bundle.

A heat exchanger (10) to provide heat exchange between fluids (24, 25), such as in a solar power plant (1), may include a first and second pipe connectors (13, 14), and a pipe bundle (17) extending between the first and second pipe connectors, with pipes (17a-17n) of the pipe bundle configured to guide a second fluid (25). The pipe bundle may be connected to the first and second pipe connectors at pipe connection points (16) so the inside of the pipes (17a-17n) is in fluid communication with cavities (15) of those connectors. The pipes may be arranged adjacent each other and extending together between the pipe connectors in a meandering manner providing a plurality of crests (20a, 20b) on the pipes between the pipe connectors, so that crests of the pipes are arranged to extend into recesses provided by one or more crests on other pipes of the pipe bundle.