INTEGRATED METHOD FOR NITROGEN-ASSISTED CARBON DIOXIDE FRACTURING AND DEVELOPMENT OF SHALE OIL RESERVOIRS

Abstract

The invention discloses an integrated method for nitrogen-assisted carbon dioxide fracturing and development of shale oil reservoirs, comprising the following steps: fracture the target shale reservoir with nitrogen-assisted carbon dioxide; after fracturing, firstly inject carbon dioxide gas into the target shale oil reservoir, and then inject nitrogen gas to push the carbon dioxide gas into the further location of the oil reservoir; shut in the well in the target shale oil reservoir; after shut-in, open the well to implement depletion production; after the first cycle of production, the slug volume of the injected gas and the shut-in time are 1.5 times of those in the previous cycle in the subsequent production, and Steps 5 to 7 are repeated for each cycle. The present invention maximizes the recovery efficiency of shale oil reservoirs; in this way, carbon dioxide gas can be used most efficiently, making the development of shale reservoir more economical and efficient; the integrated fracturing and development design enables the field operation to be streamlined and standardized, and thus different departments to cooperate each other closer.

Claims

1. An integrated method for nitrogen-assisted carbon dioxide fracturing and development of shale oil reservoirs, comprising: Step 1: Fracture the target shale oil reservoir with nitrogen-assisted carbon dioxide; Step 2: After fracturing, firstly inject carbon dioxide gas into the target shale oil reservoir, and then inject nitrogen gas to push the carbon dioxide gas into the further location of oil reservoir; Step 3: Shut in the well, to ensure the injected carbon dioxide gas can be fully recombined into shale oil , expand the volume of shale oil, reduce the viscosity, and extract the light components of shale oil; Step 4: After shut-in, open the well to implement depletion production, and terminate the first cycle of production when the reservoir pressure is depleted to ½ of the original reservoir pressure; Step 5: After the first cycle of production, inject carbon dioxide gas into the target shale oil reservoir, and then inject nitrogen gas to push the carbon dioxide gas into the further location of the oil reservoir while increasing the reservoir pressure to be close to the original reservoir pressure, where the slug volume of carbon dioxide gas and nitrogen gas is 1.5 times of that in Step 3; Step 6: Shut in the well in the target shale reservoir for 1.5 times of that in Step 3; Step 7: After shut-in, open the well to implement depletion production, and terminate the second cycle of production when the reservoir pressure is depleted to ½ of the original reservoir pressure; Step 8: In the subsequent production process, the slug volume of the injected gas and the shut-in time are 1.5 times of those in the previous cycle, and Steps 5 to 7 are repeated for each cycle; The specific fracturing operation in Step 1 is: Inject 0.1 PV high-pressure carbon dioxide to form slugs in the early stage, and then inject 0.1 PV high-pressure nitrogen; Increase the injected gas pressure to rise the pressure in the wellbore to be greater than the shale oil fracture pressure, fracturing the target shale oil reservoir and injecting proppant into the fractures so that the fractures will not be closed, which is conducive to subsequent gas injection.

2. The integrated method for nitrogen-assisted carbon dioxide fracturing and development of shale oil reservoirs according to claim 1, wherein the slug volumes of carbon dioxide gas and nitrogen gas in Step 2 are both 0.1-0.2 PV.

3. The integrated method for nitrogen-assisted carbon dioxide fracturing and development of shale oil reservoirs according to claim 2, wherein the pressures of carbon dioxide gas and nitrogen gas in Step 2 are the reservoir pressure of the target shale reservoir.

4. The integrated method for nitrogen-assisted carbon dioxide fracturing and development of shale oil reservoirs according to claim 1, wherein the shut-in time in Step 3 is 30-45 days.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0025] FIG. 1 is a diagram of wellbore structure after well completion in the shale oil reservoir;

[0026] FIG. 2 is a schematic diagram of wellbore structure for fracturing shale oil reservoir by carbon dioxide injection;

[0027] FIG. 3 is a schematic diagram of wellbore structure with nitrogen injection to maintain pressure after carbon dioxide injection for fracturing;

[0028] FIG. 4 is a schematic diagram of wellbore structure in shut-in stage after gas injection and fracturing;

[0029] FIG. 5 is a schematic diagram of wellbore structure in production stage after well opening;

[0030] FIG. 6 is a comparison diagram of recovery efficiencies in huff and puff experiments of long fractured shale cores with different gas media;

[0031] FIG. 7 is a comparison diagram of pressures in huff and puff experiments of long fractured shale cores with different gas media.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0032] The technical solutions of the present invention will be described expressly and integrally in conjunction with the appended figures. It is clear that the described embodiments are some but not all of the embodiments of the present invention. On the basis of the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative effort fall within the protection scope of the present invention.

[0033] At the end of drilling operation (after well completion), the perforated well interval is located deep in the shale oil reservoir, as shown in FIG. 1. In the operation of carbon dioxide gas injection to enhance oil recovery, the permeability of the shale oil reservoir is extremely low, resulting in the inability to inject carbon dioxide gas efficiently, thereby preventing the development effect from reaching the expected level.

[0034] Therefore, the present invention is dedicated to maximizing the use of nitrogen and carbon dioxide by utilizing nitrogen-assisted carbon dioxide for the most important tasks: (1) Fracture the shale reservoir with nitrogen-assisted carbon dioxide and (2) develop the shale oil by nitrogen-assisted carbon dioxide in the fractured reservoirs.

[0035] The integrated method for nitrogen-assisted carbon dioxide fracturing and development of shale oil reservoirs provided by the present invention can not only make full use of injected gases (nitrogen and carbon dioxide), but also organically combine fracturing with enhanced oil recovery, and the specific steps are as follows:

[0036] Step 100: Fracture the shale oil reservoir with high-pressure carbon dioxide gas, inject 0.1 PV high-pressure carbon dioxide to form slug in the early stage, and then inject 0.1 PV high-pressure nitrogen gas (as shown in FIG. 2);

[0037] Step 200: Increase the injected gas pressure to rise the pressure in the wellbore to be greater than the shale oil fracture pressure, fracturing the shale oil reservoir and injecting the designed proppant into the fractures so that the fractures will not be closed, which is conducive to subsequent gas injection; the injected carbon dioxide gas is injected into the oil reservoir through the fracture, on the one hand, to make fractures in the oil reservoir, and on the other hand, to flow into the deeper formation along the fractures, further contacting with shale oil fully and improving the recovery efficiency of shale oil;

[0038] Step 300: After fracturing, inject 0.1-0.2 PV carbon dioxide gas under the reservoir pressure to form slugs in the oil reservoir, to contact and interact with the crude oil in the further location of the shale oil reservoir, and then inject 0.1-0.2 PV nitrogen gas under the same pressure to form slugs for maintaining formation pressure and pushing the injected carbon dioxide gas to the further location of the reservoir, as shown in FIG. 3;

[0039] Step 400: Shut in the oil well for 30-45 days to fully mix shale oil with injected carbon dioxide gas, expand the volume of shale oil, reduce the viscosity, extract the light components of shale oil, improve the mobility of the crude oil, and thus improves the recovery efficiency of the crude oil, as shown in FIG. 4;

[0040] Step 500: After the shut-in process, open the well and implement depletion production under higher pressure because the injected gas (carbon dioxide, nitrogen) maintains the formation pressure, then control the pressure depletion rate of the production well, and terminate the first cycle of production when the reservoir pressure is depleted to ½ of the original reservoir pressure, as shown in FIG. 5;

[0041] Step 600: Inject 0.15-0.3 PV carbon dioxide gas into the oil well to form slugs, and subsequently inject 0.15-0.3 PV nitrogen gas under the same pressure to push the carbon dioxide gas into the further location of the reservoir while increasing the reservoir pressure to be close to original reservoir pressure;

[0042] Step 700: Shut in the oil well for 45-60 days in the oil reservoir;

[0043] Step 800: After the shut-in process, open the well to implement depletion production, control the pressure depletion rate of the production well, and terminate the second cycle of production when the reservoir pressure depletes to ½ of the original reservoir pressure;

[0044] Step 900: In the subsequent production process, the slug volume of the injected gas and the shut-in time are about 1.5 times of the previous cycle, and Steps 600 to 800 are repeated for each cycle.

[0045] In the present invention, nitrogen is used to replace carbon dioxide gas in some operations for such reasons as (1) the nitrogen gas content in the air is much greater than that of carbon dioxide gas, making the preparation process of nitrogen gas is simpler than that of carbon dioxide gas, (2) the liquefaction pressure of nitrogen is lower than that of carbon dioxide, resulting in larger volume and higher safety in the transportation, and (3) the nitrogen production requires a lower investment than carbon dioxide production, achieving more cost-effective production.

EXPERIMENTAL EXAMPLES

[0046] Huff and puff experiments of different gas media (pure carbon dioxide, carbon dioxide and nitrogen) were carried out with long shale cores after fracturing. In Experiment 1, the injected gas was pure carbon dioxide. In Experiment 2, the first injected gas was carbon dioxide, and then nitrogen was injected for maintaining the pressure.

[0047] During the experiments, the amount of carbon dioxide injected was 0.1 time of the pore volume, the shut-in time was 10 hours, and the pressure depletion rate was 30 kPa/min in each huff-and-puff cycle. After five huff-and-puff cycles, as shown in FIG. 6, the recovery efficiency reached 28.51% in Experiment 1, and reached 35.83% in Experiment 2 under the pressure maintained by nitrogen. As shown in FIG. 7, in Experiment 1, the same volume of carbon dioxide was injected in each cycle, resulting in a gradual decrease in the core pressure, which could not be maintained and the replacement energy was reduced. In Experiment 2, due to the subsequent nitrogen injection, the core pressure was maintained, improving the displacement energy in the experiment and leading to higher oil recovery factor.

[0048] The above are not intended to limit the present invention in any form. Although the present invention has been disclosed as above with embodiments, it is not intended to limit the present invention. Those skilled in the art, within the scope of the technical solution of the present invention, can use the disclosed technical content to make a few changes or modify the equivalent embodiment with equivalent changes. Within the scope of the technical solution of the present invention, any simple modification, equivalent change and modification made to the above embodiments according to the technical essence of the present invention are still regarded as a part of the technical solution of the present invention.