Abstract: A method of heating fluids that includes heating liquids within a lower portion of a vessel, using first immersion heaters and heating a gas within an upper portion of the vessel using second immersion heaters. Liquid levels in the lower portion of the vessel are controlled. Heating the gas includes heating gas within the upper portion of the common vessel within another vessel positioned within the upper portion of the common vessel.

Abstract: An electrical heater has first and second heater elements, each having a hairpin-shaped metal tube with an upstream and a downstream leg and tube ends adjacent each other. An electrical resistance wire surrounded by insulation powder extends through the tube. Electrical terminals join to the wire and protrude from each of the tube ends. Conduits enclose the upstream and the downstream legs of the heater elements, providing a continuous annular flow path. A manifold has heater element passages for end portion of the legs. An inlet passage in the manifold leads from an exterior portion of the manifold to the annular flow path surrounding the upstream leg of the first heater element. A transfer passage within the manifold leads from the annular flow path surrounding the downstream leg of the first heater element to the annular flow path surrounding the upstream leg of the second heater element.

Abstract: A system for subsea extraction of gaseous materials from and preventing the formation of hydrates.

Abstract: An apparatus, system, and method for heating fluidic material includes a sleeve positioned within a housing, with at least a portion of at least one heating element passing through the sleeve and an annulus defined by an exterior surface of the sleeve and an interior surface of the housing. A flow restrictor is positioned within the housing to control the flow of fluidic material through the sleeve relative to the flow of fluidic material through the annulus, the fluidic material through the annulus having a higher linear velocity than the flow through the sleeve.

Abstract: A method of heating fluids that includes heating liquids within a lower portion of a vessel, using first immersion heaters and heating a gas within an upper portion of the vessel using second immersion heaters. Liquid levels in the lower portion of the vessel are controlled. Heating the gas includes heating gas within the upper portion of the common vessel within another vessel positioned within the upper portion of the common vessel.

Abstract: A feed gas conditioner.

Abstract: An apparatus and method for heating fluidic materials.

Abstract: An electrical heater has first and second heater elements, each having a hairpin-shaped metal tube with an upstream and a downstream leg and tube ends adjacent each other. An electrical resistance wire surrounded by insulation powder extends through the tube. Electrical terminals join to the wire and protrude from each of the tube ends. Conduits enclose the upstream and the downstream legs of the heater elements, providing a continuous annular flow path. A manifold has heater element passages for end portion of the legs. An inlet passage in the manifold leads from an exterior portion of the manifold to the annular flow path surrounding the upstream leg of the first heater element. A transfer passage within the manifold leads from the annular flow path surrounding the downstream leg of the first heater element to the annular flow path surrounding the upstream leg of the second heater element.

Abstract: An electrical heater has a number of heater elements, each having a metal tube with an exterior end and an interior end. An electrical resistance coil is located within the tube with a conductor pin connected to the coil and protruding from the tube. Electrical insulation powder surrounds the coil within the tube. A cavity within the end of the tube receives an insulating member having a passage through which the conductor pin extends. A layer of epoxy is located between the insulating member and the powder. The tubes are arranged into three electrical phase groups. Interior conductor pins of the groups are electrically connected to each other in a Y-configuration. A phase divider of electrical insulating material has three sections dividing the electrical phase groups of the conductor pins.

Abstract: A feed gas conditioner.

Abstract: A feed gas conditioner can include embodiments having a cross heat exchanger. In embodiments, the cross heat exchanger can have a housing defining a flow passage in a first direction and a flow passage in a second direction. Heating elements in the flow passage in the first direction can heat fluidic materials. In embodiments, the feed gas conditioner can remove particles from the fluidic materials.

Abstract: A feed gas conditioner includes a passageway with a plurality of heating elements positioned within the passageway. A plurality of baffle assemblies can cause a fluid flowing through the feed gas conditioner to flow in a serpentine flow pattern so that the fluid flows transverse to at least a portion of the heating elements. The baffle assemblies can each include two or more baffle elements, the baffle elements being positioned at an angle relative to each other. The heating elements can pass through passages within one or more of the baffle elements.

Abstract: A feed gas conditioner includes a passageway with a plurality of heating elements positioned within the passageway. A plurality of baffle assemblies can cause a fluid flowing through the feed gas conditioner to flow in a serpentine flow pattern so that the fluid flows transverse to at least a portion of the heating elements. The baffle assemblies can each include two or more baffle elements, the baffle elements being positioned at an angle relative to each other. The heating elements can pass through passages within one or more of the baffle elements.

Abstract: A feed gas conditioner includes a pressure vessel that encloses at least part of a pre-heater. The pre-heater has an inlet for connection to a source of feed gas and an outlet for delivering the feed gas into the interior of the pressure vessel. An electrical heater element located within the pre-heater increases the temperature of the feed gas as it flows through the pre-heater. An expansion valve reduces the pressure of the feed gas as it flows from the pre-heater so as to initiate condensation. A super heater is at least partially located within the pressure vessel and has an inlet within the interior of the pressure vessel. A filter is in a flow path in the pressure vessel leading from the pre-heater heater to the super heater for removing condensate from the feed gas. An electrical heater element is in the super heater for heating the feed gas.

Abstract: A feed gas conditioner includes a pressure vessel that encloses at least part of a pre-heater. The pre-heater has an inlet for connection to a source of feed gas and an outlet for delivering the feed gas into the interior of the pressure vessel. An electrical heater element located within the pre-heater increases the temperature of the feed gas as it flows through the pre-heater. An expansion valve reduces the pressure of the feed gas as it flows from the pre-heater so as to initiate condensation. A super heater is at least partially located within the pressure vessel and has an inlet within the interior of the pressure vessel. A filter is in a flow path in the pressure vessel leading from the pre-heater heater to the super heater for removing condensate from the feed gas. An electrical heater element is in the super heater for heating the feed gas.

Abstract: A feed gas conditioner.

Abstract: A feed gas conditioner.

Abstract: A feed gas conditioner includes a pressure vessel that encloses at least part of a pre-heater. The pre-heater has an inlet for connection to a source of feed gas and an outlet for delivering the feed gas into the interior of the pressure vessel. An electrical heater element located within the pre-heater increases the temperature of the feed gas as it flows through the pre-heater. An expansion valve reduces the pressure of the feed gas as it flows from the pre-heater so as to initiate condensation. A super heater is at least partially located within the pressure vessel and has an inlet within the interior of the pressure vessel. A filter is in a flow path in the pressure vessel leading from the pre-heater heater to the super heater for removing condensate from the feed gas. An electrical heater element is in the super heater for heating the feed gas.

Abstract: A feed gas conditioner includes a pressure vessel that encloses at least part of a pre-heater. The pre-heater has an inlet for connection to a source of feed gas and an outlet for delivering the feed gas into the interior of the pressure vessel. An electrical heater element located within the pre-heater increases the temperature of the feed gas as it flows through the pre-heater. An expansion valve reduces the pressure of the feed gas as it flows from the pre-heater so as to initiate condensation. A super heater is at least partially located within the pressure vessel and has an inlet within the interior of the pressure vessel. A filter is in a flow path in the pressure vessel leading from the pre-heater heater to the super heater for removing condensate from the feed gas. An electrical heater element is in the super heater for heating the feed gas.

Abstract: An apparatus and method for heating fluidic materials.