DEVICE AND METHOD FOR PREVENTION OF FORMATION OF SEDIMENTS OF PARAFFIN AND ASPHALTENES DEPOSITS IN THE PIPELINE

Abstract

The device for preventing the formation of paraffin and asphaltene sediments and for the reduction of the viscosity of crude oil for use at an eruptive oil well, an oil well with pumpjack or for use at a pipeline, the stated device including six identical serially connected modules. Each module has an inlet spout and outlet spout. Crude oil under pressure passes through modules and simultaneously is in contact with different alloys. The device's elements consist of four different alloys that affect the crude oil while it passes through modules under pressure in the manner that it prevents the formation of paraffin and asphaltene deposits inside the pipeline or eruptive oil wells or oil wells with pumpjacks.

Claims

1. The device for preventing the formation of paraffin and asfaltene sediments, and for the reduction of the viscosity of crude oil for use at an eruptive oil well, an oil well with pumpjack or for use at a pipeline, the stated device comprising six identical modules which are all serially connected, whereby each module has an inlet spout and outlet spout for the entry and exit of crude oil, and crude oil under pressure passes through the device between the first alloy element and second alloy element, and simultaneously is in contact with both of the stated alloys, upon which crude oil enters into the passage formed by the second alloy element and third alloy element, and then is in contact with the outer spiral of the second alloy element and the inside of third alloy element, then continues passing through the device through a passage formed by the third alloy element and the fourth alloy element situated inside the pipe, and when passing, the crude oil is in contact with the outside of the third alloy element and the inside of the fourth alloy element, and in that manner passes through each of the 6 stated modules whereby the device's elements are composed of four different alloys wherein the composition of first alloy element, second alloy element, third alloy element and fourth alloy element are listed as follows: TABLE-US-00003 ALLOY 1 ALLOY 2 ALLOY 3 ALLOY 4 ELEMENT (10) (13) (14) (15a) Copper - Cu (w/w) 57.88% 58.88% 62.89% 63.89% Zinc - Zn (w/w) 22.00% 19.00% 16.00% 19.00% Lead - Pb (w/w) 3.30% 3.80% 3.00% 3.00% Tin - Sn (w/w) 3.60% 3.60% 3.60% 3.60% Manganese - Mn (w/w) 0.25% 0.25% 0.25% 0.25% Iron - Fe (w/w) 0.20% 0.20% 0.20% 0.20% Silicon - Si (w/w) 0.70% 0.50% 0.50% 0.20% Antimony - Sb (w/w) 0.40% 0.38% 0.36% 0.36% Aluminium - Al (w/w) 3.00% 2.50% 2.00% 1.50% Gold - Au (w/w) 2.10% 2.20% 2.30% 2.40% Silver - Ag (w/w) 2.00% 1.50% 1.30% 1.10% Platinum - Pt (w/w) 1.47% 1.19% 1.60% 1.10% Chromium - Cr (w/w) 0.60% 0.40% 0.40% 0.40% Nickel - Ni (w/w) 1.50% 2.80% 3.00% 1.40% Cobalt - Co (w/w) 0.60% 1.40% 1.30% 1.00% Tungsten - W (w/w) 0.40% 1.40% 1.30% 0.60%

2. The device according to claim 1 wherein the first alloy element is shaped in the manner that it has two right-handed spirals on its outside, which are rotated in respect to each other at 180, and at the length of 250 mm, each spiral makes one 360 revolution of its spiral, while the central part of the alloy has a passage way with an appropriately sized diameter, intended for the shielding of the device with a protective rod due to the repurposing of the device for operation at an eruptive oil well or pipeline.

3. The device according to claim 1 wherein the second alloy element also has two left-handed spirals on its outside, which are rotated in respect to each other at 180, and at the length of 250 mm, each spiral makes one 360 revolution of its spiral, and the inside surface of the alloy element is flat, while the inner diameter of the alloy element is dimensionally equal to the outer diameter of the alloy element.

4. The device according to claim 1 wherein the third alloy element also has two right-handed spirals on its outside, rotated in respect to each other at 180, and at the length of 250 mm, each spiral makes one circular rotation, and the inner diameter of the third alloy element is equal in size to the outer diameter of the alloy element.

5. The device according to claim 1 wherein the fourth alloy element is situated inside the pipe, and is shaped like the pipe, with a coarse surface, and does not contain spirals.

6. The device according to claim 1 wherein with use of the device at oil wells with pumpjacks, the protective rod, which closes the opening for the passage of the pumpjack piston pump, is removed from the device.

7. Use of the device according to claim 1 wherein it is used directly at eruptive oil wells or oil wells with pumpjacks or it is used on pipelines underwater or on land.

Description

IMPLEMENTATION OF THE INVENTION

[0023] The subject invention is presented in the accompanying figures, which show:

[0024] FIG. 1a shows the first module connected to the second module, intended for use at a pumpjack

[0025] FIG. 1b shows the final sixth module, intended for use at a pumpjack

[0026] FIG. 2a shows the first module connected to the second module, intended for use at an eruptive oil well or pipeline

[0027] FIG. 2b shows the final sixth module, intended for use at an eruptive oil well or pipeline

[0028] FIG. 3 shows the cross section of the isolator with accompanying rings

[0029] FIG. 4 shows the cross section of the inlet and outlet collectors and the cross sections of all alloy elements

[0030] FIG. 5 shows the shielding rod, joining carrier of the first and second device and the joining carrier of the last device in the series

[0031] FIG. 6 shows the main safety pipe

[0032] FIG. 7a shows the system according to the invention with all 6 modules serially connected, intended for use at a pumpjack

[0033] FIG. 7b shows the system according to the invention with all 6 modules serially connected, intended for use at an eruptive oil well

[0034] FIG. 7c shows the system according to the invention with all 6 modules serially connected, intended for use at a pipeline

[0035] FIG. 8 shows the graphical representation of viscosity for samples of untreated crude oil and treated crude oil

[0036] FIG. 9 shows the enlarged graphical representation of viscosity for samples of crude oil treated using the device according to the subject invention

[0037] FIG. 10 shows the graphical representation of viscosity (shear stress-shear rate) of samples of untreated crude oil and treated crude oil

[0038] FIG. 11 shows the graphical representation of viscosity (dynamic viscosity-shear rate) for samples of untreated crude oil and treated crude oil

[0039] FIG. 12a shows the micrograph of a sample of untreated crude oil

[0040] FIG. 12b shows the micrograph of a sample of crude oil treated with a device according to the subject invention.

[0041] The device is designed so that it can be applied at eruptive oil wells, at oil wells with pumpjacks and on land and submarine pipelines without any alternations.

[0042] The subject invention is implemented with the construction of a device that prevents the deposit of paraffin and asfaltene sediments, and reduces the viscosity of crude oil for use at eruptive oil wells, at oil wells with pumpjacks or for use on pipelines, and the stated device consists of 6 identical modules (M1), (M2), (M3), (M4), (M5), (M6), which are jointly connected in series. Each module (M1), (M2), (M3), (M4), (M5), (M6) consists of an inlet opening (1a) and outlet opening (1b) for the entry and exit of crude oil, and crude oil under pressure passes through the device between the first alloy element (10) and the second alloy elements (13), and simultaneously comes into contact with both stated alloys. Then the crude oil enters a passage made by the second alloy element (13) and the third alloy element (14), and comes into contact with the outside spiral of the second alloy element (13) and the inside of the third alloy element (14), and then continues passing through the device through a passage made by the third alloy element (14) and the fourth alloy element (15a), which is situated inside a pipe (15), and as crude oil passes through, it comes into contact with the outside of the third alloy element (14) and the inside of the fourth alloy element (15a), whereby the elements of the device (10), (13), (14), (15a) are made of four different alloys.

[0043] Compositions of the stated alloys for elements (10), (13), (14), (15a) are stated as follows:

TABLE-US-00001 ALLOY 1 ALLOY 2 ALLOY 3 ALLOY 4 ELEMENT (10) (13) (14) (15a) Copper - Cu (w/w) 55 to 65% Zinc - Zn (w/w) 16 to 22% Lead - Pb (w/w) 3.30% 3.80% 3.00% 3.00% Tin - Sn (w/w) 3.60% 3.60% 3.60% 3.60% Manganese - Mn (w/w) 0.25% 0.25% 0.25% 0.25% Iron - Fe (w/w) 0.20% 0.20% 0.20% 0.20% Silicon - Si (w/w) 0.70% 0.50% 0.50% 0.20% Antimony - Sb (w/w) 0.40% 0.38% 0.36% 0.36% Aluminium - Al (w/w) 3.00% 2.50% 2.00% 1.50% Gold - Au (w/w) 2.10% 2.20% 2.30% 2.40% Silver - Ag (w/w) 2.00% 1.50% 1.30% 1.10% Platinum - Pt (w/w) 1.47% 1.19% 1.60% 1.10% Chromium - Cr (w/w) 0.60% 0.40% 0.40% 0.40% Nickel - Ni (w/w) 1.50% 2.80% 3.00% 1.40% Cobalt - Co (w/w) 0.60% 1.40% 1.30% 1.00% Tungsten - W (w/w) 0.40% 1.40% 1.30% 0.60%

[0044] The optimal compositions of alloys for the elements of the device (10), (13), (14), (15a) are:

TABLE-US-00002 ALLOY 1 ALLOY 2 ALLOY 3 ALLOY 4 ELEMENT (10) (13) (14) (15a) Copper - Cu (w/w) 57.88% 58.88% 62.89% 63.89% Zinc - Zn (w/w) 22.00% 19.00% 16.00% 19.00% Lead - Pb (w/w) 3.30% 3.80% 3.00% 3.00% Tin - Sn (w/w) 3.60% 3.60% 3.60% 3.60% Manganese - Mn (w/w) 0.25% 0.25% 0.25% 0.25% Iron - Fe (w/w) 0.20% 0.20% 0.20% 0.20% Silicon - Si (w/w) 0.70% 0.50% 0.50% 0.20% Antimony - Sb (w/w) 0.40% 0.38% 0.36% 0.36% Aluminium - Al (w/w) 3.00% 2.50% 2.00% 1.50% Gold - Au (w/w) 2.10% 2.20% 2.30% 2.40% Silver - Ag (w/w) 2.00% 1.50% 1.30% 1.10% Platinum - Pt (w/w) 1.47% 1.19% 1.60% 1.10% Chromium - Cr (w/w) 0.60% 0.40% 0.40% 0.40% Nickel - Ni (w/w) 1.50% 2.80% 3.00% 1.40% Cobalt - Co (w/w) 0.60% 1.40% 1.30% 1.00% Tungsten - W (w/w) 0.40% 1.40% 1.30% 0.60% 100.00% 100.00% 100.00% 100.00%

[0045] Preferred Manner of Assembly of the Device

[0046] The device is designed so that it can be used at eruptive oil wells, at oil wells with pumpjacks and for external use on pipelines.

[0047] Installation of the device at an oil well with a pumpjack begins with the assembly of the first module (M1) and is carried out as follows:

[0048] Inside a ceramic carrier (4) bands (16) are installed, which are sealed with a ceramic ring (3) and a safety hoop (3a). Then the ceramic carrier (4) is fastened in the left part of the inlet collector (5). On the left part of the collector (5), a ceramic coupler (2) is then installed, which is fastened onto the left part of the collector (5) using a ring (2a) and 12 screws (2c). Next, the module carrier (1), which has an inlet spout (1a) of a size appropriate to the tubing, is fastened on the ceramic coupler (2) using 8 screws in the inner metal ring (2b) with 8 bores, which is situated in the mentioned ceramic coupler (2). The ceramic coupler (2) also assumes the role of an input isolator. The ceramic carrier (4), which is screwed onto the left part of the collector (5), has fastened to it the first alloy element (10), and then the second alloy element (13), then follows the input carrier of the first alloy element (11), which is screwed onto the second alloy element (13).

[0049] Next, the right part of the inlet collector (6) is secured onto the left part of the inlet collector (5), upon which the third alloy element (14) is screwed on the right part of the collector (6), and then a pipe (15) is screwed into the right part of the collector (6), whereby the pipe (15) connects the right part of the inlet collector (6) and the left part of the outlet collector (7). The left part of the outlet collector (7) is then screwed on the pipe (15), which connects the collector (6) and the collector (7).

[0050] The inside of the pipe (15) has an additional alloy element (15a) inserted, in the shape of the pipe. The joining carrier (12) of the first and second module is secured onto the ceramic carrier (11) of the first alloy element (10).

[0051] The ceramic coupling (9) is secured onto the right part of the outlet collector (8), via an outer metal ring (9b) with 12 bores. The ceramic coupling (9) also assumes the function of an isolator. In the collector (22) of the next module (M2), the ceramic carrier (4a) of the next module is screwed on (identical to the ceramic carrier (4) which is equipped with three bands that are identical to the three bands (16)). The collector (22) of the next module is screwed onto the ceramic coupling (9), with 8 screws on the inner ring (9a).

[0052] Then the right part of the outlet collector (8), on which elements (22) and (4a) are secured with screws, is screwed onto the left part of the outlet collector (7). The first safety pipe with a cog (18) is installed using the ceramic coupling (9), which is then secured onto the module carrier (1). Modules (M1), (M2), (M3), (M4), (M5), (M6) are serially connected thusly, a total of 6 modules, depending on the type of crude oil being treated. Each module in the series is assembled in the previously described manner.

[0053] The right part of the outlet collector (8a) of the last module (M6) in the series differs from the other modules by not having through holes for securing screws. The last module (M6) in the series ends with the module carrier (21), which is screwed onto the first safety pipe (18). When the carrier (21) is connected to the pipe (18), that assembly (21+18) is additionally fastened to the rest of the device with 8 screws (2c) in the end ring (9c) situated in the isolator (9) of the last module. The ring (9c) is only characteristic of the last module. The ceramic coupling (12a), unique only to the last module, and as an end ceramic coupling, is shorter and contains a thread. The central part of the carrier (21) has an outlet connection (1b) for tubing. The outlet connection for tubing must be of a size appropriate to the tubing. All connections of each individual module are sealed with an O-ring (25).

[0054] When installation is complete and all 6 modules (M1), (M2), (M3), (M4), (M5), (M6) are serially connected, the main safety pipe (23), which serves as additional protection and insulation, is pulled over the 6 modules. The main safety pipe (23) has a helical thread at its entry on which an entry lid (24) is fastened, and has a cog at its exit. The device is designed so that it can be lowered into all oil wells, at the greatest possible depths.

[0055] The first alloy element (10) of each module is passable, i.e. a passable canal extends through its center. The canal is intended for a pumpjack piston pump (26) so that the device can be installed at an oil well with a pumpjack. The canal is a suitable diameter for a piston size of 25.4 mm. For preparation of the device for use at an eruptive oil well and a pipeline, it is necessary to remove the joining carriers (12) of the next module, and then the first alloy element (10) is shielded with a rod (19), which is tightened with bolts (20). The first alloy element of each following module in series must be shielded in the described manner.

[0056] Each alloy element is 250 mm in length. Each module in series is approximately 610 mm in length. A series of 6 modules is preferably approximately 3660 mm in length, and between 380 mm and 410 mm in width. The stated measurements are approximate and can be changed in accordance with the dimensions of an oil well and the flow rates and pressures that must be fulfilled.

[0057] The first alloy (10) is shaped in the manner that is has two right-handed spirals on its outside, offset from one another at 180. At the length of 250 mm, each spiral makes one 360 revolution of its spiral. The central part of the alloy (10) is hollow, and of a diameter of 25.4 mm. The stated cavity is intended for shielding the device with a rod (19) when repurposing the device for operation at an eruptive oil well or pipeline. The height of the spiral element of the first alloy is preferably 34 mm.

[0058] The second alloy element (13) also has two spirals on its outside, which are offset from one another at 180. At the length of 250 mm, each spiral makes one 360 revolution of its spiral. The spirals of the element (13) are left-handed, and their height is preferably 16 mm. The inside surface of the alloy element (13) is straight. The inside diameter of the second alloy element (13) is in size equal to the outside diameter of the first alloy element (10).

[0059] The third alloy (14) also has two right-handed spirals on its outside, offset from one another at 180, and at the length of 250 mm, each spiral makes one circular revolution. The inside diameter of the alloy (14) is in size equal to the outside diameter of the alloy (13). The height of the spiral of the third alloy element is preferably 12 mm.

[0060] The fourth alloy (15a) is situated inside the pipe (15). The fourth alloy is pipe-shaped, has a coarse surface, and has no spirals.

[0061] The alloys are situated in the manner that crude oil passing through the device passes between the first alloy element (10) and second alloy element (13), and simultaneously is in contact with both stated alloys. After that, the crude oil travels further through the device, and passes through a passage formed by the second alloy element (13) and the third alloy element (14). During that passage, the crude oil is in contact with the outside spiral of the second alloy element (13) and the inside of the third alloy element (14). The crude oil then continues its passage through the device and passes through a passage formed by the third alloy element (14) and the fourth alloy element situated inside the pipe (15). During that passage, the crude oil is in contact with the outside of the third alloy element (14) and the inside of the fourth alloy element (15a). This manner of crude oil passing through the device ensures that the crude oil is simultaneously in contact with two different alloys at every moment, by which the previously described structural changes are achieved. In the described manner, the crude oil passes through each of the 6 serially-connected identical modules (M1), (M2), (M3), (M4), (M5), (M6) of the device.

[0062] Each of the 6 serially-connected modules (M1), (M2), (M3), (M4), (M5), (M6), has an input (2) and output isolator (9). Isolators (2) and (9) serve to isolate each individual module from the other modules in the series. In that manner, each module (M1), (M2), (M3), (M4), (M5), (M6) conducts the crude oil treatment separately, without impact from other modules or external conditions.

Testing Examples

[0063] Samples of crude oil and crude oil treated with the device according to the subject invention have been sampled. The following tests have been conducted: [0064] 1. Determining the rheological properties of crude oilrotational viscosimetry: Method of manufacturer Anton Paar [0065] 2. Determining the rheological properties of crude oilrotational viscosimetry (viscosity curve): Method of manufacturer Anton Paar [0066] 3. Microscopic photography of samplesphotographing samples in blue fluorescent light (A=470 nm) at magnification of 200 with an Olympus BX51 microscope

[0067] Interpretation of the Results:

[0068] From the viscosity curve (FIGS. 8-12), the rheological properties of crude oil as a function of viscosity to temperature at a constant shear rate and dynamic conditions of cooling samples of untreated crude oil and treated crude oil are visible. The viscosity curve on FIG. 10 shows the function of shear stress to shear rate at a constant temperature for samples of untreated crude oil and treated crude oil. FIG. 11 shows the function of dynamic viscosity to the shear rate at a constant temperature for samples of untreated crude oil and treated crude oil. According to photomicrographs, it can be noted that accumulations of asfaltenes are lower with treated crude oil in respect to untreated crude oil, and therefore, it can be assumed that the total content of asfaltenes is significantly lower.

[0069] The device according to the subject invention does not require any power supply, it does not have to be connected to a power source nor is any fuel required for operation. The estimated lifetime of the device in normal exploitation conditions is 10 years.

[0070] When crude oil enters the device, the temperature of the crude oil must be at least 50 C. The highest possible crude oil temperature and pressure at entry into the device is preferable. The device can be adapted to various pressures of operation.

[0071] It is possible to produce the device in all sizes. It is also possible to adjust the device to any type or amount of crude oil that is necessary to process.

[0072] Taking into account that the problem of paraffin wax and asfaltene sediments are most evident in submarine pipelines due to very low temperatures, the subject invention is especially recommended for installation at oil wells from which crude oil is extracted and transported under water (for example oil platforms), so that the problem of forming deposits can be prevented at the crude oil extraction process itself.

[0073] The device is hermetically closed and is possible to install at submarine pipelines.

[0074] The described device for preventing the formation of paraffin and asfaltene sediments, and the reduction of viscosity of crude oil for use at an eruptive oil well, at an oil well with a pumpjack, or for use at a pipeline, offers a unique device that can achieve considerable cost savings during the extraction and transport of crude oil treated thusly. Experts will find it obvious that it is possible to make numerous modifications and changes to this device according to this invention without abandoning the scope and essence of the invention.

LIST OF REFERENCED DESIGNATIONS

[0075] 1module carrier [0076] 1ainlet spout of first module [0077] 1boutlet spout of sixth module [0078] 2ceramic coupler, also input isolator [0079] 2aouter metal ring with 12 holes [0080] 2binner metal ring with 8 holes [0081] 2cscrew [0082] 3ceramic ring [0083] 3asafety hoop [0084] 4ceramic carrier [0085] 4aceramic carrier of next module in series [0086] 5left part of inlet collector [0087] 6right part of inlet collector [0088] 7left part of outlet collector [0089] 8right part of outlet collector [0090] 8aright part of outlet collector of last module in series [0091] 9ceramic coupling, also output isolator [0092] 9ainner metal ring with 8 holes [0093] 9bouter metal ring with 12 holes [0094] 9cend ring of last module [0095] 10first alloy element [0096] 11ceramic carrier of first alloy [0097] 12joining carrier of next module in series, used with pumpjacks [0098] 12aend ceramic coupling of last module [0099] 13second alloy element [0100] 14third alloy element [0101] 15pipe into which fourth alloy is inserted [0102] 15afourth alloy element [0103] 16three input bands [0104] 17three output bands [0105] 18first safety pipe [0106] 19rod for closing the passage way of the first alloy element during use at a pipeline [0107] 20bolt of protective rod (19) [0108] 21end carrier of last module [0109] 22left inlet collector of next module in series [0110] 23main safety pipe [0111] 24entry lid of main safety pipe [0112] 25O-ring [0113] 26pumpjack piston pump [0114] M1first module in series [0115] M2second module in series [0116] M3third module in series [0117] M4fourth module in series [0118] M5fifth module in series [0119] M6sixth module in series