Patent Application
20060021752
The present invention relates to subterranean heating and more particularly, to a subterranean electro-thermal heating system and method.
Heating systems may be used in subterranean environments for various purposes. In one application, a subterranean heating system may be used to facilitate oil production. Oil production rates have decreased in many of the world's oil reserves due to difficulties in extracting the heavy oil that remains in the formation. Various production-limiting issues may be confronted when oil is extracted from heavy oil field reservoirs. For example, the high viscosity of the oil may cause low-flow conditions. In oil containing high-paraffin, paraffin may precipitate out and form deposits on the production tube walls, thereby choking the flow as the oil is pumped. In high gas-cut oil wells, gas expansion may occur as the oil is brought to the surface, causing hydrate formation, which significantly lowers the oil temperature and thus the flow.
Heating the oil is one way to address these common production-limiting issues and to promote enhanced oil recovery (EOR). Both steam and electrical heaters have been used as a source of heat to promote EOR. One technique, referred to as heat tracing, includes the use of mechanical and/or electrical components placed on piping systems to maintain the system at a predetermined temperature. Steam may be circulated through tubes, or electrical components may be placed on the pipes to heat the oil.
These techniques have some drawbacks. Steam injection systems may be encumbered by inefficient energy use, maintenance problems, environmental constraints, and an inability to provide accurate and repeatable temperature control. Although electrical heating is generally considered to be advantageous over steam injection heating, electrical heating systems typically cause unnecessary heating in regions that do not require heating to facilitate oil flow. The unnecessary heating is associated with inefficient power usage and may also cause environmental issues such as undesirable thawing of permafrost in arctic locations.
Accordingly, there is a need for a subterranean electro-thermal heating system that is capable of efficiently and reliably delivering thermal input to localized areas in a subterranean environment.
Advantages of the present invention will be apparent from the following detailed description of exemplary embodiments thereof, which description should be considered in conjunction with the accompanying figures of the drawing, in which:
In general, a subterranean electro-thermal heating system consistent with the invention may be used to deliver thermal input to one or more localized areas in a subterranean environment. Applications for a subterranean electro-thermal heating system consistent with the invention include, but are not limited to, oil reservoir thermal input for enhanced oil recovery (EOR), ground water or soil remediation processes, in situ steam generation for purposes of EOR or remediation, and in situ hydrocarbon cracking in localized areas to promote lowering of viscosity of oil or oil-laden deposits. Exemplary embodiments of a subterranean electro-thermal heating system are described in the context of oil production and EOR. It is to be understood, however, that the exemplary embodiments are described by way of explanation, and are not intended to be limiting.
The length, configuration and number of the heater cable sections and the cold lead cable sections may vary depending on the application. In EOR applications, the exemplary cold lead section 16 may be at least about 700 meters in length and may extend up to about 1000 meters in length. Also, the heat generated in the cold lead section and heater cable sections may be directly related to the power consumption of these sections. In one embodiment, it is advantageous that the power consumed in the cold lead section(s) 16 be less than about 10% of the power consumed in the heater cable section(s) 12. In an EOR application, for example, power consumption in the heater cable section 12 may be about 100 watts/ft. and power consumption in the cold lead section 12 may be less than about 10 watts/ft. In another embodiment, the cold lead section(s) may be configured such that the voltage drop across the sections is less than or equal to 15% of the total voltage drop across all cold lead and heater cable sections in the system.
Those of ordinary skill in the art will recognize that power consumption and voltage drop in the cold lead sections may vary depending on the electrical characteristics of the particular system. Table 1 below illustrates the power consumption and line voltage drop for cold leads of various conductor sizes and lengths of 700, 800, 900, and 1000 meters in a system wherein the power source is a 480V single phase source and in a system wherein the power source is a 480V three phase source. Table 2 below illustrates the power consumption and line voltage drop for cold leads of various conductor sizes and lengths of 700, 800, 900, and 1000 meters in a system wherein the power source is a 600V single phase source and in a system wherein the power source is a 600V three phase source. For the exemplary configurations described in Tables 1 and 2, the cold lead conductor was sized to not exceed a 15% voltage drop or 10 watts/ft of well, and the conductor temperature was set at an average of 75° C.
One or more cold lead and heater cable sections consistent with the present invention may be provided in a variety of configurations depending on system requirements.
A system consistent with the invention may also be implemented in a segmented configuration, as shown, for example, in
The heater cable sections 12 may include any type of heater cable that converts electrical energy into heat. Such heater cables are generally known to those skilled in the art and can include, but are not limited to, standard three phase constant wattage cables, mineral insulated (MI) cables, and skin-effect tracing systems (STS).
One example of a MI cable includes three (3) equally spaced nichrome power conductors that are connected to a voltage source at a power end and electrically joined at a termination end, creating a constant current heating cable. The MI cable may also include an outer jacket made of a corrosion-resistant alloy such as the type available under the name Inconel.
In one example of a STS heating system, heat is generated on the inner surface of a ferromagnetic heat tube that is thermally coupled to a structure to be heated (e.g., to a pipe carrying oil). An electrically insulated, temperature-resistant conductor is installed inside the heat tube and connected to the tube at the far end. The tube and conductor are connected to an AC voltage source in a series connection. The return path of the circuit current is pulled to the inner surface of the heat tube by both the skin effect and the proximity effect between the heat tube and the conductor.
In one embodiment, the cold lead section 16 may be a cable configured to be electrically connected to the heater cable section 12 and to provide the electrical energy to the heater cable section 12 while generating less heat than the heater cable section 16. The design of the cold lead section 16 may depend upon the type of heater cable and the manner in which heat is generated using the heater cable. When the heater cable section 12 includes a conductor or bus wire and uses resistance to generate heat, for example, the cold lead section 16 may be configured with a conductor or bus wire with a lower the resistance (e.g., a larger cross-section). The lower resistance allows the cold lead section 16 to conduct electricity to the heater cable section 12 while minimizing or preventing generation of heat. When the heater cable section 12 is a STS heating system, the cold lead section 16 may be configured with a different material for the heat tube and with a different attachment between the tube and the conductor to minimize or prevent generation of heat.
In an EOR application, a subterranean electro-thermal heating system consistent with the present invention may be used to provide either downhole heating or bottom hole heating. The system may be secured to a structure containing oil, such as a production tube or an oil reservoir, to heat the oil in the structure. In these applications, at least one cold lead section 16 may be of appropriate length to pass through the soil to the location where the oil is to be heated, for example, to the desired location on the production tube or to the upper surface of the oil reservoir. A system consistent with the invention may also, or alternatively, be configured for indirectly heating oil within a structure. For example, the system may be configured for heating injected miscible gases or liquids which are then used to heat the oil to promote EOR.
One embodiment of a downhole subterranean electro-thermal heating system 30 consistent with the present invention is shown in
The cold lead section 36 extends through a wellhead 35 and down a section of the production tube 34 to a location along the production tube 34 where heating is desired. The length of the cold lead section 36 extending down the production tube 34 can depend upon where the heating is desired along the production tube 34 to facilitate oil flow, and can be determined by one skilled in the art. The length of the cold lead section 36 extending down the production tube 34 can also depend upon the depth of any non-target region (e.g., a permafrost region) through which the cold lead section 36 extends. In one example, the cold lead section 36 extends about 700 meters and the heater cable section 32 extends down the oil well in a range from about 700 to 1500 meters. Although one heater cable section 32 and one cold lead section 36 are shown in this exemplary embodiment, other combinations of multiple heater cable sections 32 and cold lead sections 36 are contemplated, for example, to form a segmented configuration along the production tube 34.
One example of the heating cable section 32 is a fluoropolymer jacketed armored 3-phase constant wattage cable with three jacketed conductors, and one example of the cold lead section 36 is a 3-wire 10 sq. mm armored cable. The power connector 40 may include a milled steel housing with fluoropolymer insulators to provide mechanical protection as well as an electrical connection. The power connector 40 may also be mechanically and thermally protected by sealing it in a hollow cylindrical steel assembly using a series of grommets and potting with a silicone-based compound. The end termination 42 may include fused fluoropolymer insulators to provide mechanical protection as well as an electrical Y termination of the conductors in the heater cable section 32.
As shown in
In use, the heater cable section 32 may be unspooled and fastened onto the production tube 34 as the tube 34 is lowered into a well. Before lowering the last section of the production tube 34 into the well, the heater cable section 32 may be cut and spliced onto the cold lead section 36. The cold lead section 36 may be fed through the wellhead and connected to the power source equipment 38. For non-pressurized wellheads, the cold lead section 36 may be spliced directly to the heater cable section 32 using the power connector 40.
For pressurized wellheads, a power feed-through mandrel assembly 50, shown for example in
Again, those of ordinary skill in the art will recognize a variety of cable constructions that may be used as a heater cable in a system consistent with the present invention. One exemplary embodiment of an externally installed downhole heater cable section 32 for use in non-pressurized wells is shown in
Another embodiment of a downhole subterranean electro-thermal heating system 60 includes an internally installed downhole heater cable section 62 and cold lead section 66 for use in pressurized or non-pressurized wells, as shown in
Another embodiment of a subterranean electro-thermal heating system 70 is shown in
In one embodiment, the components of the subterranean electro-thermal heating system (e.g., heater cable, cold lead, power connectors, and end terminations) may be provided separately to be assembled in the field according to the desired pattern of heated and non-target regions in the subterranean environment. For example, one or more sections of heater cable may be cut to length according to the number and dimensions of the desired heat target regions and one or more sections of cold leads may be cut to length according to the number and dimensions of the non-target regions. The heater cables and cold leads may then be interconnected and positioned in the subterranean environment accordingly.
Accordingly, a subterranean electro-thermal heating system consistent with the invention including one or more cold lead sections allows for strategic placement of heat input without unnecessary heating in certain subterranean regions. The use of the cold lead section(s) can reduce operating power usage and can minimize environmental issues such as heating through permafrost. The subterranean electro-thermal heating system further allows for segmented heat input.
While the principles of the invention have been described herein, it is to be understood that this description is made only by way of example and not as a limitation as to the scope of the invention. Other embodiments are contemplated within the scope of the present invention in addition to the exemplary embodiments shown and described herein. Modifications and substitutions by one of ordinary skill in the art are considered to be within the scope of the present invention, which is not to be limited except by the following claims.
