A hydrocarbon heating system for a hydrocarbon production and/or transportation system comprising at least one electrical conductor and an alternating current (AC) power source connected to the at least one electrical conductor. The alternating current power source generates heat in the at least one electrical conductor by providing alternating current power to the at least one electrical conductor.

A method of controlling an accumulation in a fluid system and associated apparatus is disclosed. The method comprises heating. The heating is adaptive or adaptable. The method comprises adapting the heating in accordance with a parameter associated with a development of accumulation. The parameter is monitored. An associated subsea heating system (20) for controlling an accumulation in a subsea flow line (28) is also disclosed.

A method of controlling an accumulation in a fluid system and associated apparatus is disclosed. The method comprises heating. The heating is adaptive or adaptable. The method comprises adapting the heating in accordance with a parameter associated with a development of accumulation. The parameter is monitored. An associated subsea heating system (20) for controlling an accumulation in a subsea flow line (28) is also disclosed.

A heater assembly includes three discrete components assembled in a stack. The three discrete components are: a printed circuit board, pcb, on which are provided electrically conductive tracks which generate heat when electric power is applied to the tracks, the pcb having a first major surface and a second, opposite, major surface and a periphery joining the first and second major surfaces; a heat reflective plate; and a heater assembly housing. The heat reflective plate is sandwiched between the pcb and the heater assembly housing and where the heater assembly housing is configured to fit over the heat reflective plate and the periphery of the pcb to form a closely fitted stack of the three discrete components.

A heater assembly includes three discrete components assembled in a stack. The three discrete components are: a printed circuit board, pcb, on which are provided electrically conductive tracks which generate heat when electric power is applied to the tracks, the pcb having a first major surface and a second, opposite, major surface and a periphery joining the first and second major surfaces; a heat reflective plate; and a heater assembly housing. The heat reflective plate is sandwiched between the pcb and the heater assembly housing and where the heater assembly housing is configured to fit over the heat reflective plate and the periphery of the pcb to form a closely fitted stack of the three discrete components.

Hydrate remediation systems, apparatuses, and methods of making and using same including at least one pair of electrodes detachably or fixedly attached to a pipeline or flowline in a spaced relationship so that a current may be imposed across a section of the pipeline or flowline between each pair of electrodes resulting in electrical heating of the section for a time sufficient to raise a temperature of a fluid in the section of the pipeline or flowline to a temperature above a dissociation temperature of hydrates formed in the fluid.

Hydrate remediation systems, apparatuses, and methods of making and using same including at least one pair of electrodes detachably or fixedly attached to a pipeline or flowline in a spaced relationship so that a current may be imposed across a section of the pipeline or flowline between each pair of electrodes resulting in electrical heating of the section for a time sufficient to raise a temperature of a fluid in the section of the pipeline or flowline to a temperature above a dissociation temperature of hydrates formed in the fluid.

A method for forming an electrical connection in a pipe for transporting a fluid. The pipe comprises an internal hollow tube and a heating layer comprising first fibers made of carbon. There are performed a groove-formation step in which a groove is formed in the heating layer, an interface-preparation step in which a junction layer is placed on the heating layer of the groove, and a placement step in which a connection strip comprising second fibers formed of a second electrically conducting material is wound on the junction layer.

A method for forming an electrical connection in a pipe for transporting a fluid. The pipe comprises an internal hollow tube and a heating layer comprising first fibers made of carbon. There are performed a groove-formation step in which a groove is formed in the heating layer, an interface-preparation step in which a junction layer is placed on the heating layer of the groove, and a placement step in which a connection strip comprising second fibers formed of a second electrically conducting material is wound on the junction layer.

A fluid conduit that is below grade or under water is separated from ambient water by a confined layer of liquid that may be largely undivided by solids. The separation distance between the liquid containment means and the piping or pipeline is such that the total heat transfer by natural convection and conduction from the piping or pipeline to the water containing environment is kept within limits thought necessary to adequately insulate the contents of the pipeline. A liquid may be pumped between the pipe and the means for containing the insulation so as to displace fluids from a pipeline or a heated liquid may be pumped through that space to warm the contents of the pipeline. If the insulating liquid also electrically insulates the pipe, then the pipe may be heated by passing a current directly through the pipe.