Patent Application
20240191607
This disclosure relates to using carbon dioxide (CO2), specifically liquid CO2, in hydraulic fracturing operations.
Hydraulic fracturing is a technique to stimulate production of hydrocarbons through the wellbore and to safely extract energy from an underground well. Hydraulic fracturing operations involve injecting fluids (e.g., liquids and materials such as proppants) at high pressure into a wellbore formed in a subterranean zone (e.g., a formation, a portion of a formation, multiple formations). The fluids are injected at high pressure to create small fractures in the subterranean zone. The proppants keep the fractures in the open position. By doing so, hydrocarbon entrapped in the subterranean zone flows into the wellbore through the fractures. In some instances, the fluids injected into the wellbore include carbon dioxide (CO2). Chemical interaction between the CO2 and the subterranean zone, specifically the rock formation, especially under high pressure, can alter the pore structure of the rock matrix and aid in the dissolution of the rock matrix and in the migration of minerals.
In some instances, CO2 in liquid state is used as one of the injection fluids. Liquid CO2 is a fluid state of CO2 in which the CO2 is maintained at low temperatures (e.g., −34.4° C.) and high pressure (e.g., 1.406 MPa). Compared to gaseous CO2, liquid CO2 is easier to transport.
This specification describes technologies relating to a portable system to capture and store liquid CO2, e.g., liquid CO2 used in hydraulic fracturing operations.
Certain aspects of the subject matter described here can be implemented as a method. A hydraulic fracturing operation is performed in a wellbore formed in a subterranean zone. A wellhead is installed at an entrance to the wellbore. Liquid CO2 is flowed through a pipeline located at a surface and fluidically coupled to the wellhead. The liquid CO2 is flowed into the wellbore through the wellhead to perform the hydraulic fracturing. The hydraulic fracturing operation including flowing of the liquid CO2 through the pipeline to the wellhead is stopped. A portion of the liquid CO2 is withdrawn from within the pipeline into a liquid CO2 storage container that is fluidically coupled to the pipeline at the surface.
An aspect combinable with any other aspect includes the following features. After withdrawing the portion of the liquid CO2 from the pipeline, the liquid CO2 storage container is de-coupled from the pipeline. The liquid CO2 storage container filled with the portion of the liquid CO2 is transported away from the wellbore.
An aspect combinable with any other aspect includes the following features. The withdrawn portion of the liquid CO2 is stored in the liquid state while transporting the liquid CO2 storage container.
An aspect combinable with any other aspect includes the following features. To store the withdrawn portion of the liquid CO2 in the liquid state, a temperature and a pressure of the liquid CO2 container is maintained at a temperature and a pressure, respectively, at which CO2 remains in liquid state.
An aspect combinable with any other aspect includes the following features. To flow the liquid CO2 into the wellbore through the wellhead to perform the hydraulic fracturing, multiple liquid CO2 containers, each carrying liquid CO2, are coupled to an inlet of the pipeline. An outlet of the pipeline is coupled to the wellhead. A booster pump fluidically coupled to the pipeline is operated to flow the liquid CO2 from the multiple liquid CO2 containers to the wellhead.
An aspect combinable with any other aspect includes the following features. Each liquid CO2 container is fluidically coupled to a manifold trailer fluidically coupled to the inlet of the pipeline.
An aspect combinable with any other aspect includes the following features. To withdraw a portion of the liquid CO2 within the pipeline into a liquid CO2 storage container fluidically coupled to the pipeline at the surface, a check valve is fluidically coupled to the pipeline at a location between the multiple liquid CO2 containers and the wellhead. The check valve is operated to isolate a portion of the pipeline between the check valve and the wellhead. The portion of the liquid CO2 within the isolated portion of the pipeline is withdrawn.
An aspect combinable with any other aspect includes the following features. A pipeline pump is fluidically coupled to the check valve and the liquid CO2 container into which the portion of the liquid CO2 is withdrawn. The pipeline pump is operated to draw the portion of the liquid CO2 into the liquid CO2 container.
Certain aspects of the subject matter described here can be implemented as a method that includes multiple steps. In step (a), a cemented liner of a first stage in a wellbore is perforated. In step (b), after perforating the cemented liner, slickwater fluid is flowed into the wellbore to initiate and propagate a fracture in the wellbore. In step (c), after initiating and propagating the fracture, proppant slurry is flowed into the wellbore. In step (d), after flowing proppant slurry into the wellbore, liquid CO2 is flowed into the wellbore. After flowing the liquid CO2 into the wellbore, a portion of the liquid CO2 is withdrawn into a liquid CO2 container. The liquid CO2 is maintained in the liquid state in the liquid CO2 container.
An aspect combinable with any other aspect includes the following features. To maintain the liquid CO2 in the liquid state, the liquid CO2 container is insulated to maintain a temperature and a pressure of the liquid CO2 container at a temperature and a pressure, respectively, at which CO2 remains in liquid state.
An aspect combinable with any other aspect includes the following features. To flow the liquid CO2 into the wellbore, the liquid CO2 is flowed into the wellbore through a pipeline located at a surface and fluidically coupled to the wellhead.
An aspect combinable with any other aspect includes the following features. To flow the liquid CO2 through the pipeline, multiple liquid CO2 containers, each carrying liquid CO2, are coupled to an inlet of the pipeline. An outlet of the pipeline is coupled to the wellhead. A booster pump, which is fluidically coupled to the pipeline, is operated to flow the liquid CO2 from the multiple liquid CO2 containers to the wellhead.
An aspect combinable with any other aspect includes the following features. To withdraw a portion of the liquid CO2 into the liquid CO2 storage container, a check valve is fluidically coupled to the pipeline at a location between the multiple liquid CO2 containers and the wellhead. The check valve is operated to isolate a portion of the pipeline between the check valve and the wellhead. The portion of the liquid CO2 within the isolated portion of the pipeline is withdrawn.
An aspect combinable with any other aspect includes the following features. A pipeline pump is fluidically coupled to the check valve and the liquid CO2 container into which the portion of the liquid CO2 is withdrawn. The pipeline pump is operated to draw the liquid CO2 within the isolated portion of the pipeline.
An aspect combinable with any other aspect includes the following features. Steps (a)-(d) form a fracturing stage. The hydraulic fracturing stage is stopped before withdrawing the portion of the liquid CO2 into the liquid CO2 container. After withdrawing the portion of the liquid CO2 into the liquid CO2 container, steps (a)-(d) are performed in a second, subsequent hydraulic fracturing stage.
The details of one or more implementations of the subject matter described in this specification are set forth in the accompanying drawings and the description below. Other features, aspects, and advantages of the subject matter will become apparent from the description, the drawings, and the claims.
Like reference numbers and designations in the various drawings indicate like elements.
Use of liquid CO2 as one of the hydraulic fracturing fluids can enhance the efficiency of hydraulic fracturing operation. In addition, the injected CO2 can be trapped in the subterranean zone and thereby be sequestered. Such sequestration of CO2 can have positive environmental impact. Liquefying CO2 and maintaining liquefied CO2 in liquid form can necessitate the use of specialized equipment, e.g., equipment with appropriate insulation depending on the saturation temperature and pressure. Moreover, when implemented in hydraulic fracturing operations, the liquid CO2 flows through equipment including flow equipment such as pipelines, valves, pumps, and the like. Continuous contact of such equipment with the liquid CO2 can cause damage to the equipment due to the low temperature and high pressure of the liquid CO2. One technique to reduce the continuous contact of the equipment with the liquid CO2 is to bleed the CO2 to the atmosphere. However, not only does doing so result in wastage of liquid CO2, but the addition of CO2 to the atmosphere also creates a negative environmental impact.
This disclosure describes technologies relating to a portable system to capture and store liquid CO2, specifically liquid CO2 used as in hydraulic fluids. Implementing the techniques described here can limit a need to vent CO2 to the atmosphere, thereby creating a positive environmental impact. Implementing the techniques here can also reduce a contact time between hydraulic fracturing equipment and liquid CO2. Such reduction in contact time can reduce damage to and increase the life of the equipment. The CO2 captured using the techniques described here is maintained in liquid form, allowing the liquid CO2 to be transported to different locations for storage or re-use.
In an example hydraulic fracturing sequence in two adjacent wells, a perforation gun is run into the wellbore 100 to perforate a cemented liner of the first stage in a first well (e.g., the wellbore 100). Then, slickwater fluid is flowed through the second pipeline 106 to initiate and propagate the fracture in the first well. Then, proppant slurry is flowed through the first pipeline 104 into the first well. Then, liquid CO2 is flowed through the third pipeline 108 into the first well. The hydraulic fracturing operations described here represent a first stage of hydraulic fracturing. While the pumping steps (i.e., pumping the slickwater fluid, pumping the proppant slurry and pumping the liquid CO2) are being conducted, the perforation step (i.e., running the perforation gun to perforate the cemented liner) is performed in the second well. Then, the pumping operations are performed in the second well. The sequence of operations is repeated for each hydraulic fracturing stage in an alternating fashion between the two wells.
A liquid CO2 pump truck 212, which includes pumping equipment to pump the liquid CO2 drawn from the multiple containers, is fluidically coupled to the third pipeline 108. The liquid CO2 pump truck 212 is operated to flow the liquid CO2 through the third pipeline 108 towards the wellhead 102. In some implementations, a valve 214 can be fluidically connected to the liquid CO2 pump truck 212 and to the booster pump 210. The valve 214 can be operated to control a quantity of liquid CO2 drawn from the multiple containers into the liquid CO2 truck 212.
In some implementations, a flowmeter 216 is fluidically coupled to the third pipeline 108 downstream of the valve 214. The flowmeter 216 can be used to measure a volumetric flow rate of the liquid CO2 through the third pipeline 108. Operations of the liquid CO2 pump truck 212 or the booster pump 210 or both can be controlled based on measurements obtained from the flowmeter 216.
In some implementations, a check valve 218 is fluidically coupled to the third pipeline 108 upstream of the outlet 204 of the third pipeline 108 (e.g., downstream of the flowmeter 216). The check valve 218 can permit flow of the liquid CO2 through the third pipeline 108 towards the outlet 204 of the third pipeline 108, and can prevent flow of the liquid CO2 in the opposite direction towards the inlet 202 of the third pipeline 108.
When flow of the liquid CO2 through the third pipeline 108 into the wellbore 100 through the wellhead 102 is stopped, then a quantity of liquid CO2 remains in the third pipeline 108, specifically between the inlet 202 and the outlet 204. The fluidic properties of the liquid CO2 (namely, the low temperature and high pressure) can have damaging effects on the equipment through which the liquid CO2. Moreover, unless the temperature and pressure are maintained, the liquid CO2 can transition to a different state or phase.
To avoid these drawbacks, in some implementations, a portion of the liquid CO2 can be withdrawn from within the third pipeline 108 and collected in a portable liquid CO2 container 220. The container 220 can be an insulated tank that can maintain a temperature of the liquid CO2 at a temperature at which the liquid CO2 remains in the same state/phase as when the liquid CO2 was initially introduced into the third pipeline 108. In some implementations, the liquid CO2 container 220 can be connected to refrigeration systems to maintain the liquid CO2 at the low temperatures mentioned above.
The liquid CO2 container 220 can be fluidically coupled to the third pipeline 108 to withdraw the portion of the liquid CO2. For example, a check valve 222 can be fluidically coupled to the third pipeline 108 upstream of the check valve 218 and, in some implementations, upstream of the flowmeter 216. When hydraulic fracturing operations are being performed, the check valve 222 can permit the flow of the liquid CO2 downstream of the check valve 222, and seal flow of the liquid CO2 to the liquid CO2 container 220. When hydraulic fracturing operations are stopped, the check valve 222 can switch operational states to seal the flow of the liquid CO2 downstream of the check valve 222, and to divert flow of the liquid CO2 into the liquid CO2 container 220. In this manner, the check valve 222 can be operated to isolate a portion of the third pipeline 108 in which the liquid CO2 resides. The isolated portion can be a length of the third pipeline 108 from the multiple liquid CO2 containers to the check valve 222. Alternatively or in addition, the isolated portion can be a length of the third pipeline 108 from the check valve 222 to the outlet 204 attached to the wellhead 102. In some implementations, the entire length of the third pipeline 108 from the inlet 202 to the outlet 204 can be isolated to withdraw portions of the liquid CO2 from the entire length of the third pipeline 108.
In some implementations, a pipeline pump 224 can be fluidically coupled between the check valve 222 and the liquid CO2 container 220. When the check valve 222 is in the operational state that diverts flow of the liquid CO2 into the liquid CO2 container 220, the pipeline pump 224 can be operated to draw the liquid CO2 from the third pipeline 108 and to pump the drawn liquid CO2 into the liquid CO2 container 220. Alternatively or in addition, the pipeline pump 224 can pressurize the liquid CO2 in the liquid CO2 container 220 to a pressure at which the liquid CO2 remains in the same state/phase as when the liquid CO2 was initially introduced into the third pipeline 108.
In an example operation of withdrawing the portion of the liquid CO2 into the liquid CO2 container 220, after the booster pump 210 and/or the CO2 pump truck 212 pumps the liquid CO2 from the multiple containers into the third pipeline 108, the pumps are shut-in. The check valve 218 is closed. The multiple containers are also closed. The check valve 222 is opened and the pipeline pump 224 is run. Once the liquid CO2 container 220 fills to a desired level, the pipeline pump 224 is shut-in and the check valve 222 is closed. This example operation is repeated as desired, e.g., after each fracturing stage.
After withdrawing the liquid CO2 into the container, the container can be separated, i.e., de-coupled from the pipeline from which the liquid CO2 was withdrawn. The insulation and refrigeration can maintain the temperature of the liquid CO2. The container can be sealed appropriately to maintain the pressure of the liquid CO2. The container, de-coupled from the pipeline, can be transported to any location, e.g., a location away from the wellbore, while the liquid CO2 is maintained in the same state as it was when introduced into the pipeline. The liquid CO2 can be stored at that location. Alternatively, the container can be coupled to different equipment, e.g., hydraulic fracturing equipment at a different well site, to flow the liquid CO2 out of the container into the other equipment.
In some implementations, the liquid CO2 can be replaced with supercritical CO2. In the supercritical state, CO2 has viscosity like gas and density like water. In such implementations, the liquid CO2 container 220 can be modified to maintain the CO2 in the supercritical state. For example, the CO2 container can be fitted with airtight blender, high pressure pump and manifold trucks that can maintain the CO2 in supercritical condition. Remaining equipment described here can also be similarly modified to accommodate supercritical CO2 in place of liquid CO2.
Thus, particular implementations of the subject matter have been described. Other implementations are within the scope of the following claims.
