A blending system includes a container or housing, a blade assembly, and an insert are described herein. The insert is disposed in or on the container or housing. The blade assembly includes a drive shaft. The drive shaft is rotatable. A magnet is attached to the drive shaft. Rotation of the magnet induces current in the insert. The current induces heat.

A method of improving natural gas recovery from a subterranean hydrocarbon reservoir includes at least one renewable energy source that is electrically coupled with a heat conducting element. The heat conducting element is positioned in a perforated section of a wellbore that traverses into the subterranean hydrocarbon reservoir. A temperature of the subterranean hydrocarbon reservoir is maintained above a cricondentherm temperature so that liquid condensation may be prevented at a final production time. In order to maintain the temperature within a required temperature range, an internal temperature, an internal pressure, and a set of reservoir properties are monitored and then utilized to plot a phase diagram that can be used to detect liquid condensation. If liquid condensation is detected, an electrical output of the renewable energy source is adjusted in order to control the temperature of the subterranean hydrocarbon reservoir at a producing end of a production tubing.

A method of improving natural gas recovery from a subterranean hydrocarbon reservoir includes at least one renewable energy source that is electrically coupled with a heat conducting element. The heat conducting element is positioned in a perforated section of a wellbore that traverses into the subterranean hydrocarbon reservoir. A temperature of the subterranean hydrocarbon reservoir is maintained above a cricondentherm temperature so that liquid condensation may be prevented at a final production time. In order to maintain the temperature within a required temperature range, an internal temperature, an internal pressure, and a set of reservoir properties are monitored and then utilized to plot a phase diagram that can be used to detect liquid condensation. If liquid condensation is detected, an electrical output of the renewable energy source is adjusted in order to control the temperature of the subterranean hydrocarbon reservoir at a producing end of a production tubing.

A method of improving natural gas recovery from a subterranean hydrocarbon reservoir includes at least one renewable energy source that is electrically coupled with a heat conducting element. The heat conducting element is positioned in a perforated section of a wellbore that traverses into the subterranean hydrocarbon reservoir. A temperature of the subterranean hydrocarbon reservoir is maintained above a cricondentherm temperature so that liquid condensation may be prevented at a final production time. In order to maintain the temperature within a required temperature range, an internal temperature, an internal pressure, and a set of reservoir properties are monitored and then utilized to plot a phase diagram that can be used to detect liquid condensation. If liquid condensation is detected, an electrical output of the renewable energy source is adjusted in order to control the temperature of the subterranean hydrocarbon reservoir at a producing end of a production tubing.

A method of improving natural gas recovery from a subterranean hydrocarbon reservoir includes at least one renewable energy source that is electrically coupled with a heat conducting element. The heat conducting element is positioned in a perforated section of a wellbore that traverses into the subterranean hydrocarbon reservoir. A temperature of the subterranean hydrocarbon reservoir is maintained above a cricondentherm temperature so that liquid condensation may be prevented at a final production time. In order to maintain the temperature within a required temperature range, an internal temperature, an internal pressure, and a set of reservoir properties are monitored and then utilized to plot a phase diagram that can be used to detect liquid condensation. If liquid condensation is detected, an electrical output of the renewable energy source is adjusted in order to control the temperature of the subterranean hydrocarbon reservoir at a producing end of a production tubing.

A magnetic field thermal generator has one or more heat elements comprised of rotating pipes placed so they travel across the magnetic field generated by the magnetic field chamber, with said magnetic field being generated by either permanent magnets or electromagnets. The relative motion of the heat element to the magnetic flux from the magnetic field magnets results in heat generation, as well as in the generation of Oxyhydrogen (HHO). An optional hydrogen separator may be used to separate the HHO into the Hydrogen and Oxygen components.

A rotary-induction heat generator with direct current excitation for the heating of matter, an alternating magnetic field for the generation of inductive heat, is generated with a DC coil, a static magnetic field converted into an alternating magnetic field, wherein a DC coil is received by a magnetic ring (20), wherein the magnetic ring (20) is statically connected to the housing (17) of the rotary-induction heat generator (1), and wherein the static magnetic field (51) generated by the DC coil (29) is converted into an alternating magnetic field (52) by way of a a pole wheel (19), wherein the pole wheel (19) consists of an inner pole ring (53), an outer pole ring (54) and a pole ring carrier (21, 24), by which the static magnetic field (51) is converted into an alternating field (52) in an induction ring (18) axially adjacent to the pole wheel (32).

An assembly for magnetic induction or magnetocaloric heating of a cooktop surface. One or more magnetic/electromagnetic plates are rotated by a motor or other rotary inducing input in proximity to a stationary supported magnetocaloric heating material conductive plate. Joule heating and eddy currents are generated through oscillating of magnetic fields at a given frequency when magnets/electromagnets rotate, and which is conducted through the magnetocaloric heating material via conduction and emanates from an exposed surface thereof. Conventional heating elements, such as resistor coils, are integrated into the magnetocaloric cooktop material in order to provide fast initial heat up of the materials and can be de-powered once inductive heating of the magnetocaloric material achieves desired performance levels. The housing interior can be sealed and contain a volume of any type of thermal fluid oil, lubricant or refrigerant or any other fluid with high specific heat capacity and high boiling point for providing any heat transfer properties.

The invention relates to a rotary-induction heat generator with direct current excitation for the heating of solid, or liquid, or gaseous, substances, characterised in that the alternating magnetic field required for purposes of induction, that is to say, for the generation of inductive heat, is generated with a DC coil, a static magnetic field, and this static magnetic field is converted by way of a rotating mechanical component into an alternating magnetic field, wherein a DC coil is received by a magnetic ring (20) and is preferably fixedly connected to the latter, wherein the magnetic ring (20) is statically connected to the housing (17) of the rotary-induction heat generator (1), and wherein the static magnetic field (51) generated by the DC coil (29) is converted into an alternating magnetic field (52) by way of a rotating mechanical part, specifically a pole wheel (19), wherein the pole wheel (19) consists of an inner pole ring (53), an outer pole ring (54) and a pole ring carrier (21, 24), by means of which the static magnetic field (51) is converted into an alternating field (52) in an induction ring (18) axially adjacent to the pole wheel (32), wherein the inner and the outer pole rings have a plurality of radially oriented pole extensions (46, 47), preferably more than ten, which either: a) mesh with one another, that is to say, are arranged partly radially next to one another, or overlap with one another (FIG. 5a), or b) do not overlap, but the pole extensions (46) of the inner pole ring (53) are radially spaced from the pole extensions (47) of the outer pole ring (54), wherein the pole extensions of the inner and outer pole ring have a predetermined distance (A) from one another, and preferably the number of pole extensions of the inner pole ring (53) corresponds approximately to, or is the same as, the number of pole extensions of the outer pole ring (54).

A fluid conditioning system having a housing within a fluid inlet and a fluid outlet. A rotating shaft extends within the housing and secures a conductive component exhibiting fluid flow redirecting vanes for communicating an inlet fluid flow with an outlet fluid flow. Magnets or electromagnets are arranged in a stationary array within the housing in proximity to the rotary conductive component and, upon rotating the conductive component relative to the magnetic plates, thermal conditioning of the fluid flow is generated from creation of high frequency oscillating magnetic fields and which is conducted through the rotating component for outputting through the outlet of the housing. Peltier or other thermoelectric generator elements can be incorporated into the housing. The conductive components or plates can include any of a number multi-metal/multi-alloy plate configurations.