Abstract: A heating system for a subterranean mineral formation according to embodiments of the present invention includes a casing positioned in a bore in the subterranean mineral formation, the casing having an outer surface and an inner surface, a heating element positioned within the casing, a surface connection system having a first end coupled to the heating element within the casing and a second end at a top ground surface above the subterranean mineral formation, a heat transfer fluid contained within the casing, the heat transfer fluid configured to transfer heat between the heating element and the inner surface of the casing, wherein at least a portion of the heat transfer fluid is undergoing phase changes between liquid and gas in order to regulate a temperature of the casing. Fins may be included on the outside of the casing to enhance heat transfer.

Abstract: Apparatus and methodology for self-generating high-temperature water and superheated steam for recovering embedded heavy-viscosity hydrocarbons from subterranean rock, shale, bitumen, sand formations and enabling continuous flow of released heavy-viscosity hydrocarbons using four successive spiral trough-like flowpaths, and optionally comprising an internal elongated pump member. Another embodiment promotes continuous flow of heavy-viscosity hydrocarbons through surface pipelines to tanks, railway tankcars, ships, refineries. A plurality of high-temperature, sheathed insertion heaters sustains constant high temperature to assure continuous flow of such hydrocarbons.

Abstract: A heating system for a subsurface formation includes a conduit located in a first opening in the subsurface formation. Three electrical conductors are located in the conduit. A return conductor is located inside the conduit. The return conductor is electrically coupled to the ends of the electrical conductors distal from the surface of the formation. Insulation is located inside the conduit. The insulation electrically insulates the three electrical conductors, the return conductor, and the conduit from each other.

Abstract: An electrically heatable honeycomb body has cavities through which a fluid can flow and contains at least one power distribution structure. The power distribution structure can be connected to a power source via a power feed line. At least one of the power feed line and the power distribution structure contains at least one closed-loop control element made of a material with a positive temperature coefficient (PTC) which can be placed at least in thermal contact with a fluid flowing through the honeycomb body. The electrically heatable honeycomb body permits, through the formation of a self-regulating closed-loop control element made for example from the PTC material, the implementation of a simple measure for performing closed-loop control on the heating power of the electrically heatable honeycomb body since the rest of the open-loop control or closed-loop control electronics can be significantly simplified or can even be dispensed with.

Abstract: A method for making a coiled insulated conductor heater to heat a subsurface formation includes pushing the insulated conductor heater longitudinally inside a flexible conduit using pressure. One or more cups are coupled to the outside of the insulated conductor heater. The cups maintain at least some pressure inside at least a portion of the flexible conduit as the insulated conductor heater is pushed inside the flexible conduit. The flexible conduit and the insulated conductor heater are coiled onto a coiled tubing rig.

Abstract: A method and an apparatus for establishing a hydrate free regime in a subsea production flowline before discharging into the subsea production flowline a production flow of hydrate prone hydrocarbon product pursuant to a shutdown or at an initial start of production. The hydrate free regime is achieved by injecting into the flowline a heated water volume in advance of discharging the hydrocarbon product from the subsea production system.

Abstract: A tank system can provide a predetermined cold start volume (VKS) of an operating liquid required by a liquid consumer after a cold start. The tank system can provide a urea solution to an SCR catalytic converter. The tank system includes a main tank with a filling opening through which the interior of the main tank can be filled with operating liquid. To melt a predetermined volume of the frozen liquid in a fast, efficient and complete manner, a melting device is provided. The melting device includes a melt tank which encloses a melting space and which comprises an inlet opening through which the melting space can be filled with the operating liquid from the interior of the main tank. The melting device includes a cold start heater for melting frozen liquid in the melting space. The melting space is at least as large as the cold start volume (VKS) and is smaller than the interior of the main tank.

Abstract: Systems and methods for an in situ heat treatment process that utilizes a circulation system to heat one or more treatment areas are described herein. The circulation system may use a heated liquid heat transfer fluid that passes through piping in the formation to transfer heat to the formation. In some embodiments, the piping may be positioned in at least two of the wellbores.

Abstract: A heating system for a subsurface formation includes a conduit located in an opening in the subsurface formation. An insulated conductor is located in the conduit. A material is in the conduit between a portion of the insulated conductor and a portion of the conduit. The material may be a salt. The material is a fluid at operating temperature of the heating system. Heat transfers from the insulated conductor to the fluid, from the fluid to the conduit, and from the conduit to the subsurface formation.

Abstract: An in situ conversion system for producing hydrocarbons from a subsurface formation is described. The system includes a plurality of u-shaped wellbores in the formation. Piping is positioned in at least two of the u-shaped wellbores. A fluid circulation system is coupled to the piping. The fluid circulation system is configured to circulate hot heat transfer fluid through at least a portion of the piping to form at least one heated portion of the formation. An electrical power supply is configured to provide electrical current to at least a portion of the piping located below an overburden in the formation to resistively heat at least a portion of the piping. Heat transfers from the piping to the formation.

Abstract: An electrode well for use in powerline-frequency heating of soils for decontamination of the soil. Heating of soils enables the removal of volatile organic compounds from soil when utilized in combination with vacuum extraction. A preferred embodiment of the electrode well utilizes a mild steel pipe as the current-carrying conductor to at least one stainless steel electrode surrounded by a conductive backfill material, preferably graphite or steel shot. A covering is also provided for electrically insulating the current-carrying pipe. One of the electrode wells is utilized with an extraction well which is under subatmospheric pressure to withdraw the volatile material, such as gasoline and trichioroethylene (TCE) as it is heated.

Abstract: The present invention provides a system for cooling antenna assemblies, such as subterranean RF antennas used to heat geological formations. The invention generally includes a radio frequency (RF) generator, a waveguide operatively connected to the RF generator and to the antenna, a supply of cooling gas and a cooling gas delivery tube. In one embodiment, a housing encloses the antenna, with the antenna and the waveguide defining a gas enclosure. The supply of cooling gas in this embodiment includes a regulated gas supply, a desiccator and a heat exchanger through which the gas passes. The cooling gas delivery tube is in fluid communication with the supply of cooling gas and extends downwardly within the gas enclosure to deliver cooled, dried gas to the gas enclosure. An alternative embodiment employs a coaxial transmission line as the waveguide, with the coaxial line having an inner tubular member received within a lumen of an outer tubular member.

Abstract: A device for removing deposits such as asphalt, hydrates, and paraffins from petroleum and natural gas production strings and pipelines include a tubular housing divided into a heating section at a forward end and a ballast section at a rear end, the heating section containing an electrically conducting heating medium and an electrode, and the part of the housing forming the heating section is made of an electrically conducting material, the electrode being connected to one pole of an electrical power supply and the part of the housing forming the heating section being connected to another pole of the electrical power supply, so that the heating medium and the heating section are heated by the power supply.

Abstract: An electric downhole heating system for formation heat treatment in the field of oil and gas production contains a separate wiring chamber, heating chamber, and cooling chamber, the latter being inserted between the wiring chamber and the heating chamber. The heat treatment is carried out by inserting the heater in a borehole to be treated. A gas, preferably nitrogen or air, is brought to the heater with a hose or tube. The gas flows through the wiring chamber and cooling chamber, and is heated by following a tortuous path in the heating chamber before it is expelled from the heater.