CN112081554A - Using method of viscosity reduction device of thick oil rodless submersible pump well - Google Patents
Using method of viscosity reduction device of thick oil rodless submersible pump well Download PDFInfo
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- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B36/00—Heating, cooling or insulating arrangements for boreholes or wells, e.g. for use in permafrost zones
- E21B36/04—Heating, cooling or insulating arrangements for boreholes or wells, e.g. for use in permafrost zones using electrical heaters
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B37/00—Methods or apparatus for cleaning boreholes or wells
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- General Life Sciences & Earth Sciences (AREA)
- Geochemistry & Mineralogy (AREA)
- Structures Of Non-Positive Displacement Pumps (AREA)
Abstract
The invention relates to a method for using a viscosity reduction device of a thick oil rodless submersible pump well. The technical scheme is as follows: one side of the heating wellhead device is provided with a viscosity reduction capacitor cable through a sealer, the viscosity reduction capacitor cable enters an inner cavity of the oil production string along an upper end opening of the oil production string, a safety isolation sleeve is connected to the bottom of the viscosity reduction capacitor cable, the viscosity reduction capacitor cable comprises an electric field transmission fiber core, a dielectric medium and a cable protection sleeve, the outer side of the electric field transmission fiber core is provided with the dielectric medium, the cable protection sleeve is installed on the outer side of the dielectric medium, the inner cavity bottom of the safety isolation sleeve is provided with an insulation pad, and a rectification frequency modulator is connected with an external alternating current power supply. The beneficial effects are that: the lower end of the viscosity reduction capacitor cable is isolated by the safety isolation sleeve to form a capacitor, the upper end of the viscosity reduction capacitor cable is connected to the rectified one-way pulse circuit, oil liquid in the oil production string is heated and subjected to viscosity reduction through heating of the viscosity reduction capacitor cable and electromagnetic wave phenomena, an independent system is formed between the viscosity reduction capacitor cable and the power cable of the electric submersible pump, the viscosity reduction capacitor cable and the power cable are not interfered with each other, and the viscosity reduction effect is improved.
Description
Technical Field
The invention relates to a capacitance viscosity reduction device and a method for a thick oil rodless submersible pump well, in particular to a use method of the viscosity reduction device for the thick oil rodless submersible pump well.
Background
In the process of exploiting the thick oil, the thick oil is difficult to exploit due to high viscosity and easy wax deposition, so that heating, viscosity reduction and paraffin removal are common methods. The rodless oil-submerged pump has the advantages of high efficiency, small occupied area of the upper part of a wellhead on the ground and the like, and is well applied to offshore oil exploitation and exploitation in places where land is scarce.
However, in the process of heating thick oil, due to the limitation of conditions and environment, at present, methods for heating, reducing viscosity and removing wax on thick oil wells mainly include electric heating, magnetic induction and the like, but these methods all have some defects to different degrees: one is electric heating, and because an electric heating system exists outside a thermal production pipe column, the heating efficiency is low, and a power cable of an electric submersible pump causes a circuit to frequently break down; the other method is a magnetic induction method, and the method is a method for reducing viscosity and removing wax by deriving the kinetic energy of liquid, so the application range is limited.
In view of the above situation, the present invention adopts a method of heating by a capacitor circuit, so as to solve the above problems.
Disclosure of Invention
The invention aims to provide a method for using a viscosity reduction device of a thick oil rodless submersible pump well, aiming at the defects in the prior art, the special viscosity reduction capacitor cable and a heating well head device are designed, the viscosity reduction capacitor cable is arranged in an inner cavity of an underground oil production pipe column, the lower end of the viscosity reduction capacitor cable is isolated by a safety isolation sleeve to form a capacitor, the upper end of the viscosity reduction capacitor cable is connected to a rectified unidirectional pulse circuit, and the oil liquid in the oil production pipe column is heated and reduced in viscosity by heating of the viscosity reduction capacitor cable and electromagnetic wave phenomena, so that an independent system is formed between the viscosity reduction device and an electric submersible pump power cable and is not interfered with each other.
The invention provides a method for using a viscosity reduction device of a thick oil rodless submersible pump well, which adopts the technical scheme that the viscosity reduction device comprises the following steps:
firstly, a viscosity reduction device for assembling a thick oil rodless submersible pump well,
a heating wellhead device (10) is installed on a large four-way joint (8) at the wellhead of an electric submersible pump well, an inclined convex structure (10.1) is arranged on one side of the heating wellhead device (10), an inclined hole (10.2) is arranged at the inclined convex structure, a viscosity reduction capacitor cable (12) is installed through a sealer (13), the viscosity reduction capacitor cable (12) enters an upper end opening of a production string (5) along the inclined hole (10.2) of the inclined convex structure (10.1) and then enters an inner cavity of the production string (5), the bottom of the viscosity reduction capacitor cable (12) is connected with a safety isolation sleeve (d), the viscosity reduction capacitor cable (12) comprises an electric field transmission fiber core (a), a dielectric body (b) and a cable protection sleeve (c), the dielectric body (b) is arranged on the outer side of the electric field transmission fiber core (a), and the cable protection sleeve (c) is installed on the outer side of the dielectric body (b), an insulating pad (e) is arranged at the bottom of an inner cavity of the safety isolation sleeve (d), an electric field transmission fiber core (a), a dielectric medium (b) and the bottom of the cable protection sleeve (c) are isolated to form a capacitor, the upper end of the electric field transmission fiber core (a) is positioned at a ground wellhead and connected with an output a end, namely a positive electrode, of the rectification frequency modulator, the upper end of the cable protection sleeve (c) is positioned at the ground wellhead and connected with an output c end of the rectification frequency modulator, and the rectification frequency modulator is externally connected with an alternating current power supply;
secondly, starting a switch of an alternating current power supply of a wellhead, outputting a unidirectional pulse circuit by a rectification frequency modulator, rectifying the original sine wave into unidirectional pulse waves, connecting the anode of the unidirectional pulse circuit to an electric field transmission fiber core (a) in the viscosity reduction capacitor cable (12), connecting the cathode of the unidirectional pulse circuit to a cable protective sleeve (c), enabling the electric field transmission fiber core (a) to generate the heating effect and the electromagnetic wave viscosity reduction effect, and enabling the viscosity reduction to be easy to exploit by heating oil acting on the oil in the oil production string (5); on the other hand, electromagnetic wave phenomenon is generated, and the oil liquid further generates viscosity reduction effect, so that the viscosity of the thickened oil is reduced, and the exploitation of the submersible pump is facilitated; in addition, cable protective sheath (c) are through heating well head device (10) and fluid and earth contact, avoid the well head operating personnel to electrocute.
Preferably, one side of the heating wellhead device (10) is provided with a viscosity reduction capacitor cable (12) through a sealer (13), the viscosity reduction capacitor cable (12) is arranged in the inner cavity of the oil production string (5) along the upper opening of the oil production string (5), the bottom of the viscosity reduction capacitor cable (12) is connected with a safety isolation sleeve (d), the viscosity reduction capacitor cable (12) comprises an electric field transmission fiber core (a), a dielectric medium (b) and a cable protection sleeve (c), the outer side of the electric field transmission fiber core (a) is provided with the dielectric medium (b), the cable protection sleeve (c) is arranged on the outer side of the dielectric medium (b), the bottom of the inner cavity of the safety isolation sleeve (d) is provided with an insulation pad (e) for isolating the bottoms of the electric field transmission fiber core (a), the dielectric medium (b) and the cable protection sleeve (c), and the upper end of the electric field transmission fiber core (a) is positioned at a ground wellhead and connected with the output, the upper end of the cable protective sleeve (c) is positioned at a ground wellhead and connected with an output c end of the rectification frequency modulator, and the rectification frequency modulator is externally connected with an alternating current power supply.
Preferably, the electric field transmission core (a) is a brass core, the dielectric (b) is made of a high-temperature-resistant insulating material, and the cable protective sleeve (c) is made of a medium-carbon steel plate containing 35 Mn.
Preferably, the dielectric (b) is formed by winding asbestos and glass fibers on the outer side of the electric field transmission fiber core (a), the cable protective sleeve (c) wraps a medium carbon steel plate containing 35Mn on the outer side of the dielectric (b), and then the joint is welded to form the cable protective sleeve (c) wrapped on the outer layer of the dielectric (b), and the cable protective sleeve (c) has two functions, namely, the protection of the wire core and the dielectric, and the function of serving as the other polar plate of the capacitor.
Compared with the prior art, the invention has the following beneficial effects:
1. because the two polar plates in the viscosity reduction capacitance cable are deformed into the copper bar and the cable protective sleeve, the middle insulating layer is made of high-temperature resistant materials such as asbestos and glass fiber, the length can be very long, and the viscosity reduction capacitance cable is wound by a special continuous feeding device, so that the viscosity reduction capacitance cable is more convenient to feed underground and lift up, and is more convenient to transport;
2. the cable of the power system for oil extraction through the electric submersible pump and the heating viscosity reduction system realized through the viscosity reduction capacitor cable are respectively installed and lowered into the well as two sets of systems, so that the mutual interference between the power cable of the electric submersible pump and the viscosity reduction capacitor cable is eliminated;
3. the improvement of the heating wellhead device can ensure that the viscosity reduction capacitance cable can be conveniently and obliquely inserted into an underground oil production pipe column from the heating wellhead device, and a special sealer is arranged on the heating wellhead device to ensure the reliable installation and fixation of the viscosity reduction capacitance cable; the arrangement of the heating wellhead device enables the oil production system and the viscosity reduction system to coexist;
4. the viscosity reduction capacitor cable adopts a direct-connection and cross-connection isolation principle, a rectified unidirectional pulse circuit is connected at a wellhead, the frequency can be adjusted and increased, and a cable protective sleeve on the outer layer of the viscosity reduction capacitor cable is connected with the ground, so that the safety construction of wellhead operators can be realized, and the electric shock of the operators can be avoided; in addition, the viscosity reduction capacitor cable is arranged in the inner cavity of the oil production string, so that oil in the inner cavity of the oil production string can be heated, the phenomenon that the oil is waxed due to temperature reduction and cannot be sent out of a wellhead due to reduced fluidity is avoided;
5. the implementation of viscosity reduction of the viscosity reduction capacitor cable improves the utilization efficiency of energy, and the combined action of the electromagnetic wave effect and the heat effect ensures that the viscosity reduction effect is better and obvious; in addition, the viscosity reduction is more convenient and reliable due to the application of the viscosity reduction capacitor cable, and the cable is more simple to drop into the oil production string, so that the cable is more reliable and more convenient to use and maintain;
6. the large four-way joint is provided with parallel ports, one is an inlet of a power cable and connected with an underground electric submersible pump, the other is a gas injection port, steam can be conveniently injected into the underground, and the gas injection port is positioned on two sides of the large four-way joint, so that the whole oil production process is very smooth, and the use of equipment is facilitated.
Drawings
FIG. 1 is a schematic view of the present invention in use and installed;
FIG. 2 is a schematic diagram of a heated wellhead;
FIG. 3 is a top view of the heated wellhead;
FIG. 4 is a schematic structural diagram of a section of viscosity-reducing capacitor cable;
FIG. 5 is a schematic structural diagram of a special continuous running device for winding a viscosity-reducing capacitor cable;
FIG. 6 is a schematic structural view of a double snap cap;
FIG. 7 is a side view of a double snap cap;
FIG. 8 is a schematic view of the construction of the clamp ring;
FIG. 9 is a side view of the press cap clamping ring;
FIG. 10 is a schematic structural view of a capacitive seal;
FIG. 11 is a graph of AC point sine and pulse waves and unidirectional pulse waves before and after trimming in accordance with the present invention;
in the upper diagram: an artificial well bottom 1, a casing 2, a tail pipe 3, an electric submersible pump 4, an oil production pipe column 5, a well head flange 6, a connecting bolt 7, a large four-way joint 8, a sealing steel ring 9, a heating well head device 10, an electric submersible pump power cable 11, a viscosity reduction capacitance cable 12, a sealer 13, a dynamic sealer 14 and a hanger 15,
the device comprises an oblique convex structure 10.1, an oblique hole 10.2, a heating wellhead body 10.3, a liquid outlet hole 10.4, a bolt hole 10.5, a double-closing press cap 13.1, a cable sealing element 13.2 and a press cap pressing ring 13.3;
the cable comprises an electric field transmission fiber core a, a dielectric medium b, a cable protective sleeve c, a safety isolation sleeve d, an insulating pad e and a welding seam f.
Detailed Description
The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.
Referring to fig. 4, the electric field transmission fiber core a is a brass core, the dielectric medium b is made of a high temperature resistant insulating material, and the cable protective sleeve c is made of a medium carbon steel plate containing 35 Mn.
The dielectric b is wound outside the electric field transmission fiber core a by adopting asbestos and glass fibers, the cable protective sleeve c wraps a medium carbon steel plate containing 35Mn outside the dielectric b, then the joint is welded to form the cable protective sleeve c wrapped on the outer layer of the dielectric b, and the cable protective sleeve c has two functions, namely protecting the wire core and the dielectric, and serving as the other polar plate of the capacitor.
Referring to fig. 2-3, an inclined convex structure 10.1 is arranged on one side of the heating wellhead device 10, an inclined hole 10.2 is arranged at the inclined convex structure, and a viscosity reduction capacitor cable 12 is arranged on the inclined hole 10.2 through a sealer 13; the center of heating well head body 10.3 is for going out liquid hole 10.4, and is equipped with a plurality of bolt holes 10.5 for fixed heating well head device 10.
Referring to fig. 6-8, the sealer 13 includes a double-closing pressing cap 13.1, a cable sealing element 13.2 and a pressing cap pressing ring 13.3, the double-closing pressing cap 13.1 is of a split annular structure, the outer side of the double-closing pressing cap is locked and fixed by the pressing cap pressing ring 13.3, and the lower side of the double-closing pressing cap 13.1 is provided with threads for movably connecting with an oblique convex structure; the lower end of the double-closing pressing cap 13.1 is provided with a split type cable sealing element 13.2 with inclined notches, the split type cable sealing element 13.2 is provided with a plurality of groups, and the inclined notches are staggered and wound on the viscosity reduction capacitor cable 12.
The pressing cap pressing ring 13.3 is of an annular structure and is provided with a notch, and the notch is sleeved on the outer side of the viscosity reduction capacitor cable 12 and is sleeved in two annular grooves on the outer side of the double pressing cap 13.1.
Referring to fig. 5, the viscosity reduction capacitor cable 12 is wound through a special continuous winding device, a base and a winding ring of the special continuous winding device are arranged on the base, the viscosity reduction capacitor cable 12 is continuously wound in the winding ring, a safety isolation sleeve d is welded at the outermost end of the viscosity reduction capacitor cable 12, a welding seam f is located at the joint of the safety isolation sleeve d and the viscosity reduction capacitor cable 12, an insulation pad e is arranged in an inner cavity of the safety isolation sleeve d and is made of polytetrafluoroethylene, the insulation pad is corrosion-resistant and high-temperature-resistant, the bottoms of an electric field transmission fiber core a, a dielectric medium b and a cable protection sleeve c are isolated, and a long capacitor cable is formed.
The invention provides a use method of a viscosity reduction device of a thick oil rodless submersible pump well, which comprises the following steps:
firstly, a viscosity reduction device for assembling a thick oil rodless submersible pump well,
a heating wellhead device 10 is arranged on a large four-way joint 8 at the wellhead of an electric submersible pump well, one side of the heating wellhead device 10 is provided with an oblique convex structure 10.1, an oblique hole 10.2 is arranged at the oblique convex structure, a viscosity reduction capacitance cable 12 is arranged through a sealer 13, the viscosity reduction capacitance cable 12 enters an upper end opening of an oil production string 5 along the oblique hole 10.2 of the oblique convex structure 10.1 and then enters an inner cavity of the oil production string 5, the bottom of the viscosity reduction capacitance cable 12 is connected with a safety isolation sleeve d, the viscosity reduction capacitance cable 12 comprises an electric field transmission fiber core a, a dielectric medium b and a cable protection sleeve c, the outer side of the electric field transmission fiber core a is provided with the dielectric medium b, the outer side of the dielectric medium b is provided with the cable protection sleeve c, the bottom of the inner cavity of the safety isolation sleeve d is provided with an insulation pad e, and the bottoms of the electric field transmission fiber core a, the dielectric medium b, the upper end of the electric field transmission fiber core a is positioned at a ground wellhead and connected with an output a end, namely a positive electrode, of the rectification frequency modulator, the upper end of the cable protective sleeve c is positioned at the ground wellhead and connected with an output c end of the rectification frequency modulator, and the rectification frequency modulator is externally connected with an alternating current power supply;
secondly, starting a switch of an alternating current power supply of a wellhead, outputting a unidirectional pulse circuit by a rectification frequency modulator, rectifying the original sine wave into unidirectional pulse waves, connecting the anode of the unidirectional pulse circuit to an electric field transmission fiber core a in the viscosity reduction capacitor cable 12, connecting the cathode of the unidirectional pulse circuit to a cable protective sleeve c, enabling the electric field transmission fiber core a to generate a heating effect and an electromagnetic wave viscosity reduction effect, and enabling the viscosity reduction to be easy to exploit by heating oil in the oil production string 5; on the other hand, electromagnetic wave phenomenon is generated, and the oil liquid further generates viscosity reduction effect, so that the viscosity of the thickened oil is reduced, and the exploitation of the submersible pump is facilitated; in addition, the cable protective sleeve c is in contact with the ground through the heating wellhead device 10 and oil, and electric shock of wellhead operators is avoided.
It should be noted that:
according to the technical scheme, the viscosity reduction capacitor cable is a pure capacitor circuit, and the capacitor c = d/s; the material of the electric field transmission wire core a can be selected from brass, the dielectric b is a determining factor of dielectric coefficient, and in the process, the flexibility of the dielectric is good, high temperature resistance is needed, and the insulation is good, so that the dielectric is selected from asbestos, glass fiber and other materials, and the formed capacitance can meet the requirement. The cable protective sleeve c has two functions, namely, protecting the wire core and the dielectric medium, and serving as the other polar plate of the capacitor, so that a manganese (Mn) -containing material is selected in material selection, and the medium carbon steel is selected due to the welding requirement of the welding process, so that the material is 35Mn, and the requirement can be met.
The material of the safety isolation sleeve d is 35Mn, the purpose is grinding and welding, and the functions are as follows: the friction on the cable protective sleeve c is reduced, so that the capacitor cable is convenient to put in, and meanwhile, the insulating pad e is protected and cannot be damaged when the capacitor cable is put in; and the protective insulating pad material is polytetrafluoroethylene, which is corrosion-resistant and high-temperature resistant, and has the function of blocking the passage of the cable protective sleeve c and the circuit of the electric field transmission wire core a, so that the capacitor cable forms a real capacitor circuit.
The basic principle of the invention is as follows:
the basic principles of viscosity reduction and paraffin removal of the capacitor circuit are as follows: the first is the thermal effect of the current, i.e. high temperature is generated; the second is pulse electromagnetic wave (or electromagnetic field) generated by alternating pulse current (i.e. pulse electricity). Specifically, the rectification frequency modulator comprises a rectifier and a frequency modulator, wherein the rectifier is used for rectifying an original sine wave to convert the original sine wave into a unidirectional pulse wave, and the frequency modulator is used for adjusting the frequency to be high frequency. Of course, in order to satisfy the "low-pass high-frequency-blocking" feature of the capacitor.
Because the capacitor circuit has the characteristics of ' alternating current blocking direct current ' and ' low frequency and high frequency blocking, the capacitor cable heating and electromagnetic wave transmitting can be realized, and the capacitor heating technology of the thick oil rodless submersible pump well is realized.
Embodiment 2, the viscosity reduction device of a thick oil rodless submersible pump well provided by the invention comprises a casing 2, a tail pipe 3, an electric submersible pump 4, an oil production string 5, a well head flange 6, a large four-way joint 8, a sealing steel ring 9, a heating well head device 10 and an electric submersible pump power cable 11, wherein the oil production string 5 is installed in the casing 2, the electric submersible pump 4 and the tail pipe 3 are installed at the lower end of the oil production string 5, and the upper end of the oil production string is fixed on the large four-way joint 8 through a hanger 15; big cross 8 swing joint is at well head flange 6, installs heating well head device 10 on the big cross 8, and electric submersible pump power cable 11 is connected to electric submersible pump 4 in the pit through dynamic seal 14 and big cross 8, still is equipped with the gas injection mouth on the big cross 8, and its improvement part is: the viscosity reduction capacitor cable 12 is installed on one side of the heating wellhead device 10 through a sealer 13, the viscosity reduction capacitor cable 12 enters the inner cavity of the oil production string 5 along the opening at the upper end of the oil production string 5, the bottom of the viscosity reduction capacitor cable 12 is connected with a safety isolation sleeve d, the viscosity reduction capacitor cable 12 comprises an electric field transmission fiber core a, a dielectric medium b and a cable protection sleeve c, the dielectric medium b is arranged on the outer side of the electric field transmission fiber core a, the cable protection sleeve c is installed on the outer side of the dielectric medium b, an insulation pad e is arranged at the bottom of the inner cavity of the safety isolation sleeve d, the bottoms of the electric field transmission fiber core a, the dielectric medium b and the cable protection sleeve c are isolated, the upper end of the electric field transmission fiber core a is located at the ground wellhead and connected with the output a end of a rectification frequency modulator, and the upper end of the cable protection sleeve, the rectification frequency modulator is externally connected with an alternating current power supply.
Referring to fig. 4, the electric field transmission fiber core a is a brass core, the dielectric medium b is made of a high-temperature-resistant insulating material, the cable protective sleeve c is made of a medium carbon steel plate containing 35Mn, the medium carbon steel plate containing 35Mn is wrapped on the outer side of the dielectric medium b by the cable protective sleeve c, then the joint is welded to form the cable protective sleeve c wrapped on the outer layer of the dielectric medium b, and the cable protective sleeve c has two functions, namely, the protection of the wire core and the dielectric medium, and the other function of serving as the other polar plate of the capacitor.
The difference from the embodiment 1 is that: the dielectric b is formed by winding an insulating layer, asbestos or glass fiber on the outer side of the electric field transmission fiber core a in the following manufacturing mode: firstly, an insulating layer is sprayed on the surface of a brass core, then asbestos or glass fiber is wound on the outer surface of the brass core sprayed with the insulating layer, then a medium carbon steel plate containing 35Mn is wrapped on the outer side of a dielectric b, and then a joint is welded to form a cable protective sleeve c wrapped on the outer layer of the dielectric b.
The formula of the insulating layer on the surface of the brass core is as follows: according to the weight portion, the material comprises 45-60 portions of chlorinated butyl rubber, 40-55 portions of silicon dioxide, 9-16 portions of expanded graphite, 20-35 portions of aluminum hydroxide, 4-10 portions of diisononyl phthalate, 10-15 portions of pottery clay and 5-15 portions of mica powder. The insulating layer material prepared by the invention has excellent insulating and flame-retardant properties, is not easy to ignite, has high use safety performance and obviously prolongs the service life.
In this embodiment, the preferable formulation of the insulating layer is: the coating comprises, by weight, 60 parts of chlorinated butyl rubber, 55 parts of silicon dioxide, 16 parts of expanded graphite, 35 parts of aluminum hydroxide, 10 parts of diisononyl phthalate, 15 parts of pottery clay and 15 parts of mica powder. The insulating layer material prepared by the invention has excellent insulating and flame-retardant properties, is not easy to ignite, has high use safety performance and obviously prolongs the service life.
Embodiment 3, the viscosity reduction device of a thick oil rodless submersible pump well provided by the invention comprises a casing 2, a tail pipe 3, an electric submersible pump 4, an oil production string 5, a well head flange 6, a large four-way joint 8, a sealing steel ring 9, a heating well head device 10 and an electric submersible pump power cable 11, wherein the oil production string 5 is installed in the casing 2, the electric submersible pump 4 and the tail pipe 3 are installed at the lower end of the oil production string 5, and the upper end of the oil production string is fixed on the large four-way joint 8 through a hanger 15; big cross 8 swing joint is at well head flange 6, installs heating well head device 10 on the big cross 8, and electric submersible pump power cable 11 is connected to electric submersible pump 4 in the pit through dynamic seal 14 and big cross 8, still is equipped with the gas injection mouth on the big cross 8, and its improvement part is: the viscosity reduction capacitor cable 12 is installed on one side of the heating wellhead device 10 through a sealer 13, the viscosity reduction capacitor cable 12 enters the inner cavity of the oil production string 5 along the opening at the upper end of the oil production string 5, the bottom of the viscosity reduction capacitor cable 12 is connected with a safety isolation sleeve d, the viscosity reduction capacitor cable 12 comprises an electric field transmission fiber core a, a dielectric medium b and a cable protection sleeve c, the dielectric medium b is arranged on the outer side of the electric field transmission fiber core a, the cable protection sleeve c is installed on the outer side of the dielectric medium b, an insulation pad e is arranged at the bottom of the inner cavity of the safety isolation sleeve d, the bottoms of the electric field transmission fiber core a, the dielectric medium b and the cable protection sleeve c are isolated, the upper end of the electric field transmission fiber core a is located at the ground wellhead and connected with the output a end of a rectification frequency modulator, and the upper end of the cable protection sleeve, the rectification frequency modulator is externally connected with an alternating current power supply.
The differences from examples 1 and 2 are: the rectification frequency modulator is changed into a rectification device, the frequency of the generated unidirectional pulse circuit is doubled to be 100HZ, and the figure 11 shows that i is4And i1In contrast, the frequency f is doubled.
The formula of the insulating layer on the surface of the brass core is as follows: according to the weight portion, the material comprises 45 portions of chlorinated butyl rubber, 45 portions of silicon dioxide, 12 portions of expanded graphite, 28 portions of aluminum hydroxide, 6 portions of diisononyl phthalate, 12 portions of pottery clay and 10 portions of mica powder. The insulating layer material prepared by the invention has excellent insulating and flame-retardant properties, is not easy to ignite, has high use safety performance and obviously prolongs the service life.
At present, the process is tested in places such as a victory oil field, a hong kong oil field, a Jidong oil field and the like, and the results are as follows:
the oil transportation pressure is the pressure when entering a ground oil transportation pipe, the oil transportation pressure is generally between 10 and 15MPa, and the relative viscosity of the liquid can meet the ground oil transportation requirement when the pressure (namely the air pressure) is not more than 10 MPa.
Liquid output temperature: the viscosity of the liquid is related to the temperature, and the temperature is kept and the improved energy comes from the heating of the viscosity reduction capacitor cable, so that the output temperature of the liquid, namely the temperature output from the inside of the sleeve to the outside, is an important index of the heating effect, and the temperature after the heating reaches more than 40 ℃, and the oil transportation pressure meets the requirement, so that the oil transportation requirement is met.
Relative viscosity of sampled liquid: in order to facilitate the control of experimental conditions, 20 ℃ is adopted, so that the viscosity temperature of a sample directly retrieved from a well head is 20 ℃ or is converted into 20 ℃ again to be compared as a standard, wherein the reference substance is water; wherein, the relative viscosity value of the sampling liquid is flowable at 3-5, and is not flowable when more than 5, and the values in the table are all more than 5, which indicates that the sampling liquid is viscous and does not flow when normally at 20 ℃, and measures are required to be taken for heating and viscosity reduction.
Therefore, the invention can be used for obtaining a conclusion through long-term test, the oil liquid of the oil extraction pipe column is heated and viscosity reduced through the heating of the viscosity reduction capacitor cable and the electromagnetic wave phenomenon, an independent system is formed between the viscosity reduction capacitor cable and the power cable of the electric submersible pump, the system is not interfered with each other, the failure rate is low, the exploitation requirement of the electric submersible pump and the ground oil transportation requirement are met, and the service life is long.
The above description is only a few of the preferred embodiments of the present invention, and any person skilled in the art may modify the above-described embodiments or modify them into equivalent ones. Therefore, any simple modifications or equivalent substitutions made in accordance with the technical solution of the present invention are within the scope of the claims of the present invention.
Claims (4)
1. The use method of the viscosity reduction device of the thick oil rodless submersible pump well is characterized by comprising the following steps of:
firstly, a viscosity reduction device for assembling a thick oil rodless submersible pump well,
a heating wellhead device (10) is installed on a large four-way joint (8) at the wellhead of an electric submersible pump well, an inclined convex structure (10.1) is arranged on one side of the heating wellhead device (10), an inclined hole (10.2) is arranged at the inclined convex structure, a viscosity reduction capacitor cable (12) is installed through a sealer (13), the viscosity reduction capacitor cable (12) enters an upper end opening of a production string (5) along the inclined hole (10.2) of the inclined convex structure (10.1) and then enters an inner cavity of the production string (5), the bottom of the viscosity reduction capacitor cable (12) is connected with a safety isolation sleeve (d), the viscosity reduction capacitor cable (12) comprises an electric field transmission fiber core (a), a dielectric body (b) and a cable protection sleeve (c), the dielectric body (b) is arranged on the outer side of the electric field transmission fiber core (a), and the cable protection sleeve (c) is installed on the outer side of the dielectric body (b), an insulating pad (e) is arranged at the bottom of an inner cavity of the safety isolation sleeve (d), an electric field transmission fiber core (a), a dielectric medium (b) and the bottom of the cable protection sleeve (c) are isolated to form a capacitor, the upper end of the electric field transmission fiber core (a) is positioned at a ground wellhead and connected with an output a end, namely a positive electrode, of the rectification frequency modulator, the upper end of the cable protection sleeve (c) is positioned at the ground wellhead and connected with an output c end of the rectification frequency modulator, and the rectification frequency modulator is externally connected with an alternating current power supply;
secondly, starting a switch of an alternating current power supply of a wellhead, outputting a unidirectional pulse circuit by a rectification frequency modulator, rectifying the original sine wave into unidirectional pulse waves, connecting the anode of the unidirectional pulse circuit to an electric field transmission fiber core (a) in the viscosity reduction capacitor cable (12), connecting the cathode of the unidirectional pulse circuit to a cable protective sleeve (c), enabling the electric field transmission fiber core (a) to generate the heating effect and the electromagnetic wave viscosity reduction effect, and enabling the viscosity reduction to be easy to exploit by heating oil acting on the oil in the oil production string (5); on the other hand, electromagnetic wave phenomenon is generated, and the oil liquid further generates viscosity reduction effect, so that the viscosity of the thickened oil is reduced, and the exploitation of the submersible pump is facilitated; in addition, cable protective sheath (c) are through heating well head device (10) and fluid and earth contact, avoid the well head operating personnel to electrocute.
2. The use method of the viscosity reduction device of the thick oil rodless submersible pump well according to claim 1 is characterized in that: the viscosity reduction capacitor cable (12) is installed on one side of the heating wellhead device (10) through a sealer (13), the viscosity reduction capacitor cable (12) enters an inner cavity of the oil production string (5) along an upper end opening of the oil production string (5), the bottom of the viscosity reduction capacitor cable (12) is connected with a safety isolation sleeve (d), the viscosity reduction capacitor cable (12) comprises an electric field transmission fiber core (a), a dielectric medium (b) and a cable protection sleeve (c), the outer side of the electric field transmission fiber core (a) is provided with the dielectric medium (b), the cable protection sleeve (c) is installed on the outer side of the dielectric medium (b), the bottom of the inner cavity of the safety isolation sleeve (d) is provided with an insulation pad (e) which isolates the bottoms of the electric field transmission fiber core (a), the dielectric medium (b) and the cable protection sleeve (c), and the upper end of the electric field transmission fiber core (a) is located at a ground wellhead and connected with an output, the upper end of the cable protective sleeve (c) is positioned at a ground wellhead and connected with an output c end of the rectification frequency modulator, and the rectification frequency modulator is externally connected with an alternating current power supply.
3. The use method of the viscosity reducer of the thick oil rodless submersible pump well according to claim 1 is characterized in that: the electric field transmission fiber core (a) is a brass core, the dielectric medium (b) is made of a high-temperature-resistant insulating material, and the cable protective sleeve (c) is made of a medium-carbon steel plate containing 35 Mn.
4. The use method of the viscosity reducer of the thick oil rodless submersible pump well according to claim 3 is characterized in that: the electric field transmission cable is characterized in that the dielectric body (b) is wound outside the electric field transmission fiber core (a) by adopting asbestos and glass fibers, the cable protective sleeve (c) wraps a medium carbon steel plate containing 35Mn outside the dielectric body (b), then the joint is welded to form the cable protective sleeve (c) wrapped on the outer layer of the dielectric body (b), and the cable protective sleeve (c) has two functions, namely, the protection of the wire core and the dielectric body, and the other function of serving as the other polar plate of the capacitor.
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| CN1062017A (en) * | 1990-12-04 | 1992-06-17 | 国际壳牌研究有限公司 | Low resistance electrical heater |
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