Method of treating crude oil with ultrasound vibrations and microwave energy

Abstract

The present invention relates to methods of treating heavy crude oil on the surface or in situ. The methods of the present invention include: (a) mixing the heavy crude oil with a solvent; (b) subjecting the mixture to ultrasonic vibrations; and (c) subjecting mixture treated with ultrasonic vibrations to microwave energy.

Claims

1. A method of treating bitumen, the method including: (a) mixing the bitumen with a water-free solution of a solvent and an aromatic hydrocarbon; (b) subjecting the bitumen and the water-free mixture to ultrasonic vibrations; and (c) subjecting the mixture treated with ultrasonic vibrations to microwave energy, wherein the solvent is selected from the group consisting of: alkanes, alcohols, fuel liquids, reformates, frac fluids and any combinations thereof, and the aromatic hydrocarbon is benzene, a benzene derivative or a combination thereof.

2. The method of claim 1, wherein the method is free of using polar substances.

3. The method of claim 1, wherein the method is free of using sensitizers.

4. The method of claim 1, wherein the solvent is provided as a mixture between the solvent and a suitable dilutant.

5. An in situ method for the treatment of a bitumen deposit, the method including: (a) disposing a water-free solution consisting of a solvent and an aromatic hydrocarbon into the bitumen deposit, such that a mixture is created between the solvent, the aromatic hydrocarbon and the bitumen in the deposit; (b) subjecting the mixture in the bitumen deposit to ultrasonic vibrations; and (c) subjecting the bitumen deposit to microwave energy, wherein the solvent is selected from the group consisting of: alkanes, alcohols, fuel liquids, reformates, frac fluids and any combinations thereof, and the aromatic hydrocarbon is benzene, a benzene derivative or a combination thereof.

6. The method of claim 5, wherein the method further includes extracting the bitumen from the oil deposit treated with ultrasonic vibrations and microwave energy.

7. The method of claim 5, wherein the method is free of using polar substances.

8. The method of claim 5, wherein the method is free of using sensitizers.

9. The method of claim 5, wherein the solvent is provided as a mixture between the solvent and a suitable dilutant.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The following FIGURE illustrate various aspects and preferred and alternative embodiments of the invention.

(2) FIG. 1. Graph illustrating the effect of ultrasonics on radiofrequency (RF) absorption index.

DESCRIPTION OF THE INVENTION

(3) Definitions

(4) Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Also, unless indicated otherwise, except within the claims, the use of or includes and and vice versa. Non-limiting terms are not to be construed as limiting unless expressly stated or the context clearly indicates otherwise (for example including, having and comprising typically indicate including without limitation). Singular forms including in the claims such as a, an and the include the plural reference unless expressly stated otherwise. In order to aid in the understanding and preparation of the within invention, the following illustrative, non-limiting, examples are provided.

(5) By in situ it is meant that the process takes place at the crude oil deposit or oil reservoir, and without extracting the crude oil from the crude oil deposit.

(6) The term hydrocarbon matrix as used in this document refers to a raw or crude mixture which includes crude oil and a substrate. The crude oil may include heavy crude oil. The substrate may be a mixture of sand, sandstone, sedimentary rocks, clays, carbonate and so forth. Hydrocarbon matrices include, for example, oil sand or oil shale in an oil deposit, and oil sand or oil shale taken or mined from an oil deposit.

(7) The term media as used in this document refers to substances capable of transferring ultrasonic energy from an ultrasonic transducer.

(8) The term oil deposit refers to an area with reserves of recoverable crude oil or petroleum. Oil deposits include conventional oil deposits, shale oil deposits, oil sand deposits and carbonate oil reservoirs.

(9) The term recovery as used in this documents means techniques for extracting crude oil from an oil deposit or reservoir.

(10) Overview

(11) The present invention relates to a process of treating heavy crude oils on the surface or in deposits with ultrasonic vibrations and microwaves.

(12) The microwave processes of the prior art use water. The polarized medium (i.e. water) is used so that the medium in the oil deposit will absorb the microwaves. The use of a polarized medium in a non-polarized environment (the oil deposit) is quite inefficient. Accordingly, a method that is free of polarized media has been developed herein.

(13) In one embodiment, the method of treating heavy crude oil may include: (a) mixing the heavy crude oil with a solvent and an aromatic hydrocarbon; (b) subjecting the mixture to ultrasonic vibrations; and (c) subjecting mixture treated with ultrasonic vibrations to microwave energy.

(14) Oil deposits do not heat with microwave because bitumen is not an absorber of microwave, or electromagnetic, radiation. The inventor, unexpectedly, discovered that ultrasonic vibrations may change the nature of a mixture of oil and a solvent to facilitate the absorbance of microwaves. As a result, polarized media, such as water, or sensitizers may not be needed. The combination of ultrasonics and microwaves without the addition of a polar substance may reduce the viscosity of the crude oil by reducing the length of the hydrocarbons in the crude oil matrix. Lower viscosity may allow for pumpable oil, easier extraction of the oil from the deposit, and facilitate transportation to an upgrading processing centre without use of steam, heat and other high cost processes.

(15) The methods of the present invention may be carried out in situ or on the surface.

(16) The solvent may be any suitable solvent, preferably a solvent that dissolves poorly in water. The solvent may be selected from the group of solvents comprising: non-cyclic hydrocarbons, aromatic hydrocarbons, alcohols, reformates, frac fluid, and any combination thereof. The solvent may be provided as a mixture of solvent and one or more suitable dilutants. Suitable dilutants or carriers may include diesels or other liquid fuels. The solvent/dilutant ratio may be from 1-99% v/v solvent and 1-99% v/v dilutant.

(17) The aromatic hydrocarbon may be benzene, chemical compounds derived from benzene, chemical compounds having a benzene ring or any combination thereof. In one embodiment, the aromatic hydrocarbon may be xylene, toluene, or a combination thereof. Isomers of aromatic hydrocarbons are also included.

(18) In another embodiment of the present invention, the method may be free or devoid of using polar substances. In one aspect of the present invention, the method may be free of using water. In yet another embodiment, the method of the present invention may be free or devoid of sensitizers, such as those described in US Pat. Publ. No. 2004/0031731.

(19) In Situ

(20) In one embodiment, the present invention provides for an in situ method of treating heavy crude oil deposits. The method, in one embodiment, may include: (a) disposing a solvent and an aromatic hydrocarbon into the heavy crude oil deposit, such that a mixture is created between the solvent, the aromatic hydrocarbon, and the heavy crude oil in the deposit; (b) subjecting the mixture in the heavy crude oil deposit to ultrasonic vibrations; and (c) subjecting the oil deposit to microwave energy. In one embodiment, the method further includes (d) extracting the heavy crude oil from the deposit.

(21) In one embodiment the present invention describes in situ and on surface methods of extracting hydrocarbons from a heavy oil formation, such as an oil sand deposit or oil shale deposit. The in situ method of extracting hydrocarbons from an oil deposit may start by disposing (including pouring or injection) a solvent into the deposit. A bore or well may be made in the oil deposit, and the solvent may be disposed (including injecting or pouring) into the bore. The solvent may be any suitable solvent, preferably one that dissolves poorly in water. Examples of solvents may include non-cyclic hydrocarbon such as pentanes, hexanes, heptanes or octanes, aromatic hydrocarbons, and alcohols. Diesels, gasoline frac fluid, reformate compositions or any combination thereof may also be used. The solvent may be provided as a mixture of solvent and one or more suitable dilutants. Suitable dilutants or carriers may include diesels or other liquid fuels. The solvent/dilutant ratio may be from 1-99% v/v solvent and 1-99% v/v/dilutant.

(22) The in situ method may also include disposing (injecting or pouring) an aromatic hydrocarbon into the oil deposit. The aromatic hydrocarbon may be disposed before, together with, or after disposing the solvent. The aromatic hydrocarbon may be benzene, chemical compounds derived from benzene, chemical compounds having a benzene ring or any combination thereof.

(23) The in situ method may continue by subjecting the deposit to ultrasonic vibrations. The ultrasonic vibrations may start before, during or after disposing the solvent and aromatic hydrocarbon.

(24) An ultrasonic transducer may be brought into the well and may contact with the non-polar substance which has been poured into the well. From about 1 kHz to about 80 kHz of ultrasonic vibration may be used. However, a person of ordinary skill in the art may understand that less than 1 kHz or more than 80 kHz may be used. When the ultrasonic transducer is turned on, the vibrations in the non-polar solvent may turn the liquid into an ultrasonic media which may dissolve the heavy crude oil in the oil deposit. The dissolved heavy crude oil may in turn create even more ultrasonic media from the solvent/crude oil mixture which continues to spread further into the matrix of the oil deposit. Furthermore, heat may be generated from this method as a result of exothermic reactions within the dissolving process.

(25) The in situ method may continue by subjecting the deposit to microwave energy. The microwave energy may be applied during treatment with the ultrasound transducer or after treatment with the ultrasound transducer. A microwave tool may be brought into the well and may contact with the mixture in the deposit. Microwave irradiation may be provided by a tool such as that described in US Pat. Application Publ. No. 2009/0260818, the contents of which are incorporated herein by reference. The microwave tool of this patent application includes a microwave source that can be switched on or off, and which is connected, by means of a cable, to one or more transmitting antennae mounted on pads at the ends of arms which can be used to position the antennae close to the borehole wall. The tool is placed downhole by means of a wireline cable (other conveyance means such as drill pipe or coiled tubing can also be used), and is activated downhole when near a region of interest.

(26) The solvents, ultrasonic vibrations and microwave energy may contribute in reducing the viscosity of the heavy crude oil which may flow be pumped out of the well, thereby extracting the hydrocarbons (such as bitumen present in oil sands) in situ from the oil deposit.

(27) In order to aid in the understanding and preparation of the within invention, the following illustrative, non-limiting, examples are provided.

EXAMPLE 1

(28) In order to demonstrate the methods of the present invention, the following experiments were carried out.

(29) 1. Substances

(30) Samples of oil sand were obtained from The Alberta Research Council. Diesel was obtained from a local retail gas station; xylene was obtained from a local paint store.

(31) 2. Tools

(32) 1.3 KWatt microwave oven manufactured by the Toshiba Corporation of Tokyo, Japan in 1987. The oven's rated maximum output is 720 Watt. The oven is model # ERX-1790C-1.

(33) The temperatures were measured using a Reed R2001 infrared thermometer rated to read temperatures from 50 to 280 degrees C.

(34) A Whaledent Biosonic UC1-110 operating at 55 KHz, was used to test the effects of ultrasonics on oil sand.

(35) A ceramic bowl having a mass of 61.g.

(36) A 100 ml beaker. Mass of beaker: 50.2 g

(37) 3. Experiments

(38) A standardized index of measure was used to determine the absorption effect of microwaves. The 100 ml beaker containing 80 ml of room temperature water was placed in the centre of the microwave oven. Substances were placed in a small ceramic bowl and the bowl placed about 1 cm from the beaker of water inside the microwave oven. The oven door was closed and the oven was turned on at maximum level for 30 seconds. The temperature of both substances and water was taken before and after being exposed to microwaves by the oven. The mass of each substance was taken prior to microwaving.

(39) The temperatures were measured using the infrared thermometer. There is a spot size of 8:1 for the read area of the beam of the thermometer. The infrared thermometer was placed about 8 cm from items measured resulting in a spot size of measurement of 1 cm diameter, which ensured a reasonably accurate measure of temperature. Items were placed on a nearby wooden table while temperature was being measured.

(40) The addition to a beaker of water in the microwave oven is used as a control fro comparison and ensures a standard accurate measure of microwave absorption. Furthermore, since a standard amount of microwave energy is emitted into the oven, the comparison of the heating of the beaker of water and heating of the substance leads to the ability to calculate an index which indicates the comparative ability of substances to be heated by microwaves.

(41) In each measure, both the bowl and beaker were thoroughly washed and dried and brought to ambient room temperature. The empty bowl and beaker of water achieved almost the same amount of heating when heated together. Both rose from 21.5 degrees to 41.5 degrees in 30 seconds.

(42) In turn, various substances were placed in the bowl and the experiment repeated. Some substances were ultrasonically treated for 15 minutes and some were not.

(43) Two main experiments were carried out: one without the use of ultrasound vibrations (results shown in Table 1 and FIG. 1) and the other with ultrasound (results shown in Table 2 and FIG. 1). Within each experiment, three sub-experiments were carried out using the following substances or mixtures of substances: For Experiment 1 (without ultrasound): (a) oil sand (OS) and diesel, (b) diesel and xylene, and (c) oil sand, diesel and xylene; for Experiment 2 (with ultrasound): (a) oil sand and diesel, (b) oil sand, diesel and xylene, and (c) oil sand only.

(44) 4. Results

(45) FIG. 1, table 1 (Experiment without ultrasonic treatment) and table 2 (experiment with ultrasonic treatment) illustrate the results of the present experiments. The index is calculated by taking the inverse.

(46) 5. Discussion

(47) Radio waves in the form of microwaves have been tried in downhole and oil bearing formations with little success. Although there are reports of heating of pockets of water in subsurface formations, this heating is minor and to date, using microwaves to heat oil bearing formations has not proved to be economically successful.

(48) The experiments described herein were conducted to investigate the effect of ultrasonic treatment on solvents and oil sand regarding the ability of these substances to absorb microwaves and thereby enabling this technology to be used in an economically viable way in treating oil products for sub-surface extraction and on surface.

(49) It has previously been shown by the Inventor that solvents would be absorbed efficiently into a formation and into oil bearing substances. It appears there is some alteration of the molecular structure of the resultant ultrasonically treated mixture or solution. This has been shown to be true using chemical analysis of carbon chain abundance before and after ultrasonic treatment.

(50) Microwaves may be easily absorbed by polar chemical substances such as water and not by non-polar substances. The inventor now tested whether ultrasonics can alter the structure of non-polar solvents and petroleum such that a small degree of polarization forms within molecular structure of the solution/mixture.

(51) The inventor has found that a solution/mixture of diesel and bitumen, placed in a microwave oven, heats quickly to dangerous levels. The inventor has also found that ultrasound, with diesel in downhole formations, is absorbed into a solution/mixture.

(52) The results illustrated in FIG. 1 unexpectedly show that some substances, notably Xylene mixed with diesel, have significant changes in their ability to absorb microwave energy after being treated with ultrasound vibrations.

(53) TABLE-US-00001 TABLE 1 Without Ultrasonic Treatment (dT wat delta T dt mix)/ water delta mass Mass (g) T1 C T2 C delta T C d T/Kg T mixture mix index Experiment #1 Oil Sand and Diesel mass of OS 7.6 mass of Diesel 7.9 Mixture 15.5 22.4 32.6 10.2 0.658065 24 1.548387 0.645833 Water 21.8 56 34.2 Experiment #2 Diesel & Xylene no oil sand mass of Diesel 5.2 mass of Xylene 5.3 Mixture 10.5 23.5 38 14.5 1.380952 7.5 0.714286 1.4 Water 22 44 22 Experiment #3 Oil sand, Diesel and Xylene mass of OS 7.8 mass of Diesel 5.9 mass of Xylene 5.9 Mixture 19.6 24.2 35.2 11 0.561224 7.7 0.392857 2.545455 Water 22.3 41 18.7

(54) TABLE-US-00002 TABLE 2 With Ultrasonic Treatment delta T (dT wat water dt mix)/ Mass delta delta T mass (g) T1 C T2 C T C d T/Kg mixture mix inverse Experiment #4 Oil Sand and Diesel mass of OS 44 mass of Diesel 27.7 Mixture 21.6 23.3 37.2 13.9 0.643519 12.7 0.587963 1.700787 Water 22.4 49 26.6 Experiment #5 Oil Sand, Diesel & Xylene mass of OS 43 mass of Diesel 22.1 mass of Xylene 22.7 Mixture 22.4 25.4 37.6 12.2 0.544643 2 0.089286 11.2 Water 23.7 37.9 14.2 Experiment #6 Oil Sand only mass of OS 43.4 Mixture 24.4 24.4 32.5 8.1 0.331967 22 0.901639 1.109091 Water 23.1 53.2 30.1

(55) Through the embodiments that are illustrated and described, the currently contemplated best mode of making and using the invention is described. Without further elaboration, it is believed that one of ordinary skill in the art can, based on the description presented herein, utilize the present invention to the full extent.

(56) Although the description above contains many specificities, these should not be construed as limiting the scope of the invention, but as merely providing illustrations of some of the presently embodiments of this invention. Thus the scope of the invention should be determined by the appended claims and their legal equivalents, rather than by the examples given.