ROTATING APPARATUS AND METHOD FOR MEASURING ACID-ROCK REACTION CHARACTERISTICS IN HIGH TEMPERATURE AND PRESSURE

Abstract

A rotating apparatus and a method for measuring acid-rock reaction characteristics in high temperature and pressure are provided. The apparatus for measuring the acid-rock reaction characteristics includes: a first reactor configured to react a rock disk with an acid; a second reactor configured to produce a spent acid through reaction of a rock with an acid aqueous solution, and to introduce the spent acid into the first reactor; and a sample extractor configured to extract a predetermined amount of acid reacting with the rock disk in the first reactor. Accordingly, the rock disk is rotated in the acid at high temperature and pressure in consideration of the reaction characteristics of the rock dissolved in the acid, and then a predetermined amount of acid reacting the rock is obtained with time. In addition, a flow of an acid in a real reservoir can be implemented by producing a spent acid and then reacting the rock disk with the spent acid at a reservoir condition.

Claims

1. An apparatus for measuring acid-rock reaction characteristics, the apparatus comprising: a first reactor configured to make a reaction of a rock disk with an acid; a second reactor configured to produce a spent acid through reaction of a rock with an acid aqueous solution, and to introduce the spent acid into the first reactor; and a sample extractor configured to extract a predetermined amount of acid reacting with the rock disk in the first reactor.

2. The apparatus of claim 1, wherein the first reactor is configured to make a reaction of the rock disk with the acid in a high temperature and pressure as reservoir condition.

3. The apparatus of claim 2, wherein the second reactor is configured to produce the spent acid by reacting the rock with the acid aqueous solution in the high temperature and pressure as reservoir condition.

4. The apparatus of claim 3, wherein the first reactor comprises: a first reaction vessel in which the rock disk reacts with the acid; a first heating jacket configured to maintain a temperature of the first reaction vessel in the reservoir condition; a first magnetic drive configured to rotate the rock disk when the rock disk reacts with the acid; and a first sensor configured to measure internal temperature and pressure of the first reaction vessel.

5. The apparatus of claim 4, wherein the second reactor comprises: a second reaction vessel configured to store the spent acid produced through the reaction of the rock with the acid aqueous solution in the reservoir condition; a second heating jacket configured to maintain a temperature of the second reaction vessel in the reservoir condition; a second magnetic drive configured to rotate a permeable container containing the rock when the rock reacts with the acid aqueous solution; a second sensor configured to measure internal temperature and pressure of the second reaction vessel; and a cylinder configured to introduce the spent acid stored in the second reaction vessel into the first reactor by pushing the spent acid to the outside of the second reaction vessel.

6. The apparatus of claim 5, further comprising a data acquisition device configured to acquire temperature and pressure data of the first reactor and the second reactor from the first sensor and the second sensor, and to adjust the temperatures of the first reaction vessel and the second reaction vessel by controlling the first heating jacket and the second heating jacket.

7. The apparatus of claim 6, wherein the data acquisition device is configured to adjust rotating speeds of the first magnetic drive and the second magnetic drive.

8. The apparatus of claim 1, wherein the sample extractor comprises: a sampling line configured to have a predetermined amount of acid loaded therein; a sampling tank configured to store an acid; a first sampling valve configured to move the acid reacting with the rock disk in the first reactor to the sampling line; and a second sampling valve configured to move the acid loaded in the sampling line to the sampling tank.

9. The apparatus of claim 8, wherein the sampling tank is configured to make it easy to acquire a sample by storing an acid and reducing pressure prior to acquiring a sample during an experiment conducted in high pressure.

10. The apparatus of claim 1, further comprising a vent configured to discharge internal fluid to the outside after the reaction finishes in the first reactor and the second reactor.

11. The apparatus of claim 10, wherein the vent comprises: a neutralization tank configured to load a neutralizing agent therein to neutralize an acid; a first vent valve configured to move internal fluid of the first rector to the neutralization tank after the reaction finishes; and a second vent valve configured to move internal fluid of the second reactor to the neutralization tank after the reaction finishes.

12. The apparatus of claim 1, wherein the acid extracted by the sample extractor is used to calculate a dissolution rate and a diffusion coefficient of the acid reacting with the rock through the first reactor and the second reactor.

13. The apparatus of claim 1, wherein the acid reacting with the rock disk is at least one acid selected from the group consisting of a hydrochloric acid, an organic acid, and an acid blend, and wherein the rock comprises a rock which has reactivity with an acid, the rock comprising a carbonate rock.

14. A method for measuring acid-rock reaction characteristics, the method comprising the steps of: producing a spent acid by reacting a rock with an acid aqueous solution, and introducing the spent acid into a first reactor; reacting a rock disk with an acid in the first reactor; and extracting a predetermined amount of acid reacting with the rock disk in the first reactor.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0026] For a more complete understanding of the present disclosure and its advantages, reference is now made to the following description taken in conjunction with the accompanying drawings, in which like reference numerals represent like parts:

[0027] FIG. 1 is a view showing a configuration of a rotating apparatus for measuring acid-rock reaction characteristics according to an embodiment of the present disclosure; and

[0028] FIG. 2 is a detailed diagram of the rotating apparatus for measuring the acid-rock reaction characteristics shown in FIG. 1.

DETAILED DESCRIPTION OF THE INVENTION

[0029] The present disclosure will be described in more detail with reference to the accompanying drawings.

[0030] FIG. 1 is a view showing a configuration of a rotating apparatus for measuring acid-rock reaction characteristics according to an embodiment of the present disclosure.

[0031] The rotating apparatus for measuring the acid-rock reaction characteristics according to an embodiment of the present disclosure measures a dissolution rate, a diffusion coefficient, and an order of reaction of a rock having a property of dissolving in an acid through an acid-rock rotating reaction in high temperature and pressure.

[0032] In addition, the rotating apparatus for measuring the acid-rock reaction characteristics according to an embodiment of the present disclosure refers to an apparatus for measuring a dissolving ability of an acid and for analyzing reaction characteristics with a rock after producing a spent acid (an acid having already induced a reaction).

[0033] The rotating apparatus for measuring the acid-rock reaction characteristics according to an embodiment of the present disclosure includes a main reactor 100, a pre-processing reactor 200, a sample extractor 300, a vent 400, and a data acquisition device 500 as shown in FIG. 1.

[0034] The main reactor 100 makes a reaction of a rock disk, which is a reaction target and is fixed to a shaft of magnetic drive, with an acid in a high temperature and pressure condition. The main reactor 100 and the pre-processing reactor 200 may be connected with each other via a pipeline.

[0035] The pre-processing reactor 200 produces a spent acid by reacting a rock and an acid aqueous solution with each other in a high temperature and pressure as reservoir condition, and stores the spent acid.

[0036] The sample extractor 300 extracts a predetermined amount of acid reacting with the rock in the main reactor 100.

[0037] The data acquisition device 500 controls reaction vessel temperatures of the reactors 100 and 200 and a rotation speed of the magnetic drive, based on pressure and temperature of the main reactor 100 and the pre-processing reactor 200.

[0038] The main reactor 100 and the pre-processing reactor 200 are connected with the vent 400. The vent 400 discharges internal fluid of the apparatus to the outside after the experiment finishes.

[0039] Hereinafter, the rotating apparatus for measuring the acid-rock reaction characteristics according to an embodiment of the present disclosure will be described in detail with reference to FIG. 2. FIG. 2 is a detailed diagram of the rotating apparatus for measuring the acid-rock reaction characteristics of FIG. 1.

[0040] The main reactor 100 which makes a reaction of the rock disk with the acid includes a main reaction vessel 110, a first heating jacket 120, a first magnetic drive 130, a first temperature sensor 140, and a first pressure sensor 150.

[0041] The main reaction vessel 110 is a vessel in which the rock and the acid react with each other, and the first heating jacket 120 is installed to surround the main reaction vessel 110 to set and maintain the temperature of the main reaction vessel 110 according to the reservoir condition.

[0042] The first magnetic drive 130 is a portion that has the rock disk fixed at an end of the shaft connected therewith, and where the fixed rock disk reacts with the acid, and constantly maintains a reaction area between the rock and the acid by rotating the rock disk at a predetermined speed.

[0043] The rock disk, which is a reaction target, may be a carbonate rock, and does not exclude other rocks having reactivity with an acid. In addition, the acid reacting with the rock disk may be at least one acid selected from the group consisting of an hydrochloric acid, an organic acid, and an acid blend, and does not exclude other acids.

[0044] The first temperature sensor 140 and the first pressure sensor 150 may identify whether the temperature and pressure of the main reaction vessel 110 are maintained in the reservoir condition by measuring the internal temperature and pressure of the main reaction vessel 110.

[0045] The pre-processing reactor 200 which produces the spent acid by reacting the rock with the acid includes a pre-processing reaction vessel 210, a second heating jacket 220, a second magnetic drive 230, a second temperature sensor 240, a second pressure sensor 250, a cylinder 260, and a permeable container 270.

[0046] The pre-processing reaction vessel 210 is a vessel that stores the spent acid which is produced through the reaction of the rock and the acid aqueous solution in the reservoir condition, and the second heating jacket 220 is installed to surround the pre-processing reaction vessel 210 and to maintain the temperature of the pre-processing reaction vessel 210 in the reservoir condition.

[0047] The second magnetic drive 230 may have the rock for producing a spent acid positioned in the permeable container 270 disposed at an end of the shaft connected therewith, and may rotate the permeable container 270 at a regular speed when the acid and the rock react with each other.

[0048] The rock which is a target for producing the spent acid may be a carbonate rock, and does not exclude other rocks having reactivity.

[0049] The second temperature sensor 240 and the second pressure sensor 250 may measure internal temperature and pressure of the pre-processing reaction vessel 210, thereby identifying whether the temperature and pressure of the pre-processing reaction vessel 210 are maintained in the reservoir condition.

[0050] In addition, the cylinder 260 pushes the spent acid stored in the pre-processing reaction vessel 210 to the outside, thereby introducing the spent acid into the main reactor 100.

[0051] The sample extractor 300 which extracts a predetermined amount of acid reacting with the rock in the main reactor 100 includes a first sampling valve 310, a second sampling valve 320, a sampling line 330, and a sampling tank 340.

[0052] The first sampling valve 310 serves to move the acid reacting with the rock disk in the main reactor 100 to the sampling line 330. The sampling line 330 may be fabricated to hold a fluid of 10 ml.

[0053] The second sampling valve 320 enables the acid loaded in the sampling line 330 to move to the sampling tank 340, such that a predetermined amount of sample can be obtained. The sampling tank 340 serves to store the acid before a sample is obtained at an experiment conducted under high pressure, and enables a sample to be obtained by reducing the pressure.

[0054] The vent 400, which discharges internal fluid generated in the apparatus to the outside after the reaction of the rock with the acid finishes, includes a first vent valve 410, a second vent valve 420, and a neutralization tank 430.

[0055] The first vent valve 410 may introduce the fluid introduced into the main reactor 100 and the fluid generated through the reaction of the acid and the rock into the neutralization tank 430 of the vent 400.

[0056] The second vent valve 420 may introduce the fluid introduced from the pre-processing reactor 200 and the fluid generated by producing the spent acid into the neutralization tank 430 of the vent 400.

[0057] The neutralization tank 430 may load a sodium hydroxide aqueous solution therein as a neutralizing agent to neutralize the acid, and may neutralize the fluid introduced from the main reactor 100 and the pre-processing reactor 200, and then discharge the fluid to the outside of the apparatus.

[0058] The data acquisition device 500 may acquire temperature and pressure data of the main reactor 100 and the pre-processing reactor 200 measured by the first temperature sensor 140 and the first pressure sensor 150 of the main reactor 100 and the second temperature sensor 240 and the second pressure sensor 250 of the pre-processing reactor 200, and may adjust the temperatures of the main reactor 100 and the pre-processing reactor 200 by controlling the first heating jacket 120 and the second heating jacket 220 based on the acquired temperature and pressure data.

[0059] In addition, the data acquisition device 500 may adjust the rotating speed of the first magnetic drive 130 for rotating the shaft at which the rock disk, which is a reaction target, is fixed in the main reactor 100, and the rotating speed of the second magnetic drive 230 for rotating the shaft to which the permeable container 270 for producing the spent acid is connected in the pre-processing reactor 200.

[0060] Up to now, the rotating apparatus and method for measuring the acid-rock reaction characteristics in high temperature and pressure have been described with reference to preferred embodiments.

[0061] The apparatus and THE method for measuring the acid-rock reaction characteristics according to an embodiment of the present disclosure produce the spent acid at the reservoir condition and then reacts the rock disk with the spent acid in the single apparatus, such that a more practical flow of an acid can be implemented in a reservoir.

[0062] In particular, a dissolution rate and a diffusion coefficient can be more exactly measured by rotating the rock disk in an acid at high temperature and pressure in consideration of the reaction characteristics of the rock dissolved in the acid, and then obtaining a predetermined amount of acid reacting the rock with time, and a flow of an acid in a real reservoir can be implemented by producing a spent acid of the reservoir condition and then reacting the rock disk with the spent acid in the single apparatus.

[0063] In addition, while preferred embodiments of the present disclosure have been illustrated and described, the present disclosure is not limited to the above-described specific embodiments. Various changes can be made by a person skilled in the art without departing from the scope of the present disclosure claimed in claims, and also, changed embodiments should not be understood as being separate from the technical idea or prospect of the present disclosure.