CN118579868A - Oil and gas field fracturing flowback fluid processing control method, device, equipment and storage medium - Google Patents

Abstract

The present invention relates to the technical field of oil and gas field fracturing flowback fluid processing, and discloses an oil and gas field fracturing flowback fluid processing control method, device, equipment and storage medium. The method obtains the fracturing operation task of each fracturing operation point in each fracturing operation sub-area, generates the fracturing flowback fluid processing task of each fracturing operation sub-area, and then adjusts the fracturing flowback fluid processing speed of each fracturing operation sub-area and the call between different fracturing flowback fluid recycling pools by considering the state of the fracturing flowback fluid recycling pool network, thereby ensuring that each fracturing flowback fluid recycling pool is always within the range of the maximum buffer amount, thereby ensuring that the fracturing operation point can continuously discharge and process the fracturing flowback fluid, and the fracturing operation tasks of multiple fracturing operation points can be executed on time, thereby improving the fracturing flowback fluid processing efficiency, reducing the energy consumed in the processing process, and maximizing the enterprise benefits.

Description

Oil and gas field fracturing flowback fluid processing control method, device, equipment and storage medium

Technical Field

The present invention relates to the technical field of oil and gas field fracturing flowback fluid processing, and in particular to an oil and gas field fracturing flowback fluid processing control method, device, equipment and storage medium.

Background Art

The treatment of oil and gas field fracturing flowback fluid is a complex and critical process, involving a variety of treatment methods to ensure that the discharged wastewater meets environmental standards. In oil and gas field fracturing flowback fluid, fracturing fluid flowback means that after the fracturing fluid is injected into the ground, the fracturing purpose is completed, and the remaining fracturing fluid must be returned to the ground for treatment or reuse. However, with the rapid development of oilfield chemicals, the on-site construction conditions have higher and higher requirements for fracturing fluids. Chelating agent-type corrosion and scale inhibition fracturing fluids meet the needs of the comprehensive development of oilfield additives in the future. In the current oilfield exploitation process, facing the problem of hydraulic fracturing using a large amount of water resources and serious pollution of fracturing flowback fluids, the reuse of flowback fluids is the future trend of the oil and gas field industry development, both from the perspective of cost and environmental protection.

At present, the main problem with the treatment of fracturing return fluid is the insufficient number of fracturing return fluid treatment equipment (cost and site limitations). Therefore, in actual engineering applications, a group of fracturing return fluid treatment equipment is usually used at several fracturing operation points. Although this solves the problem of insufficient quantity, it also leads to the need for coordination of fracturing return fluid treatment tasks with very high accuracy among multiple fracturing operation points. Otherwise, it will affect the fracturing operation tasks of multiple fracturing operation points and affect the production progress of the enterprise.

Therefore, how to improve the efficiency of fracturing backflow treatment, reduce the energy consumed in the treatment process, and maximize corporate benefits is a technical problem that needs to be solved urgently.

Summary of the invention

The main purpose of the present invention is to provide a method, device, equipment and storage medium for controlling fracturing flowback fluid in oil and gas fields, aiming to solve the above technical problems.

To achieve the above object, the present invention provides a method for controlling the treatment of oil and gas field fracturing flowback fluid, the method comprising the following steps:

Acquire a fracturing operation task table of a target operation area; wherein the target operation area includes a plurality of fracturing operation sub-areas, each of the fracturing operation sub-areas has a plurality of fracturing operation points, and the fracturing operation task table includes a fracturing operation task of each fracturing operation point in a target period;

Based on the fracturing operation task, determining fracturing flowback fluid processing information for each fracturing operation point;

Generate a fracturing flowback fluid treatment task for each fracturing operation sub-area based on the fracturing flowback fluid treatment information of each fracturing operation point;

Acquire status information of a fracturing flowback fluid reuse pool network, and generate a fracturing flowback fluid processing control instruction according to the status information and the fracturing flowback fluid processing task;

The fracturing flowback fluid processing control instruction is sent to the fracturing flowback fluid buffer scheduling device and the fracturing flowback fluid processing device, and the fracturing flowback fluid scheduling action and the fracturing flowback fluid processing action are respectively executed to complete the fracturing flowback fluid processing in the target operation area.

Optionally, the step of obtaining a fracturing operation task list for a target operation area specifically includes:

Accessing a fracturing operation task database, and extracting the fracturing operation tasks that are assigned to each fracturing operation point and need to be performed within a target period;

The comparison relationship table between the fracturing operation points and the fracturing flowback fluid reuse pool is called to obtain the fracturing flowback fluid reuse pool corresponding to each fracturing operation point, and several fracturing operation points using the same fracturing flowback fluid reuse pool are regarded as fracturing operation points in the same fracturing operation sub-area.

Optionally, based on the fracturing operation task, the step of determining the fracturing flowback fluid processing information of each fracturing operation point specifically includes:

Extracting fracturing operation parameters in the fracturing operation task; wherein the fracturing operation parameters include fracturing operation time and fracturing fluid usage;

Query the corresponding fracturing flowback rate of each fracturing operation point in the current operation stage, and generate the fracturing flowback fluid discharge volume of each fracturing operation point at each moment in the target time period according to the fracturing operation time, the fracturing fluid usage and the fracturing flowback rate;

According to the timestamp information at each moment and the corresponding fracturing flowback fluid discharge volume, the fracturing flowback fluid processing information of each fracturing operation point is generated.

Optionally, based on the fracturing flowback fluid processing information of each fracturing operation point, the fracturing flowback fluid processing task steps of each fracturing operation sub-area are generated, specifically including:

According to the discharge volume of fracturing flowback fluid at each fracturing operation point at each moment, the total discharge volume of fracturing flowback fluid at each fracturing operation sub-area at each moment is calculated;

The total amount of the fracturing flowback fluid discharged at each moment is used as the fracturing flowback fluid processing task of the fracturing flowback fluid reuse pool corresponding to each fracturing operation sub-area.

Optionally, the state information of the fracturing flowback fluid reuse pool network is obtained, and the fracturing flowback fluid processing control instruction step is generated according to the state information and the fracturing flowback fluid processing task, specifically including:

Acquire status information of a fracturing flowback fluid recycling pool network; wherein the fracturing flowback fluid recycling pool network includes a plurality of fracturing flowback fluid recycling pools corresponding to each fracturing operation sub-area, and the status information includes a connection relationship between any two fracturing flowback fluid recycling pools and a fracturing flowback fluid buffer volume of each fracturing flowback fluid recycling pool;

The total amount of fracturing flowback fluid discharged at each moment in each fracturing operation sub-area in the fracturing flowback fluid processing task is extracted, and a fracturing flowback fluid processing control instruction is generated according to the relationship between the sum of the total amount of fracturing flowback fluid discharged and the fracturing flowback fluid buffer amount and the buffer amount upper limit of each fracturing flowback fluid reuse pool; wherein the fracturing flowback fluid processing control instruction includes a fracturing flowback fluid buffer scheduling instruction and a fracturing flowback fluid processing instruction.

Optionally, the step of generating a fracturing flowback fluid processing control instruction according to the relationship between the sum of the total discharge amount of the fracturing flowback fluid and the buffer amount of the fracturing flowback fluid and the buffer amount upper limit of each fracturing flowback fluid reuse pool specifically includes:

According to the relationship between the sum of the total discharge amount of the fracturing flowback fluid and the buffer amount of the fracturing flowback fluid at each moment and the buffer amount upper limit of each fracturing flowback fluid reuse pool, the fracturing flowback fluid processing speed of the fracturing flowback fluid processing equipment corresponding to each moment is adjusted;

Based on the fracturing flowback fluid processing speed, generating a fracturing flowback fluid processing control instruction for controlling the processing speed of a fracturing flowback fluid processing device;

Wherein, the fracturing flowback fluid processing control instruction includes a first control instruction for controlling a solid-liquid separation device and a second control instruction for controlling an aeration device;

The first control instruction is configured to control the access usage ratio of the filtering device and the filter pressing device, and the second control instruction is configured to control the pump gas power level of the aeration device.

Optionally, according to the relationship between the sum of the total discharge amount of the fracturing flowback fluid and the fracturing flowback fluid buffer amount at each moment and the buffer amount upper limit of each fracturing flowback fluid reuse pool, the step of adjusting the fracturing flowback fluid processing speed of the fracturing flowback fluid processing equipment corresponding to each moment specifically includes:

Determine whether, during the process of executing the fracturing flowback fluid treatment in the target period at the fracturing flowback fluid standard treatment speed corresponding to the fracturing flowback fluid treatment control instruction with the lowest power at each moment within the target period, there is a fracturing flowback fluid buffer volume obtained by subtracting the sum of the fracturing flowback fluid standard treatment speeds at each moment before the target moment from the sum of the total discharge volume of the fracturing flowback fluid calculated at the target moment and the fracturing flowback fluid buffer volume, which exceeds the buffer volume upper limit;

If so, adjust the fracturing flowback fluid processing control instruction so that the sum of the powers at each moment in the target time period is greater than that before the adjustment, re-execute the above-mentioned judgment step until there is no fracturing flowback fluid buffer volume exceeding the buffer volume upper limit at the target moment, and use the fracturing flowback fluid standard processing speed corresponding to the current fracturing flowback fluid processing control instruction as the fracturing flowback fluid processing speed of the fracturing flowback fluid processing equipment in the final target time period;

If the sum of the powers at each moment in the target time period has been adjusted to the maximum, and there is still a fracturing flowback fluid buffer volume at the target moment that exceeds the buffer volume upper limit, a third control instruction for controlling the fracturing flowback fluid buffer scheduling device is generated according to the connection relationship between the fracturing flowback fluid reuse pools;

According to the third control instruction, the fracturing return fluid buffer volume of the target fracturing return fluid reuse pool is dispatched to the adjacent fracturing return fluid reuse pool, and the above-mentioned judgment process is re-executed in the target fracturing return fluid reuse pool and the adjacent fracturing return fluid reuse pool until the fracturing return fluid buffer volume in each fracturing return fluid reuse pool at the target time does not exceed the buffer volume upper limit.

In addition, in order to achieve the above-mentioned purpose, the present invention also provides an oil and gas field fracturing flowback fluid processing control device, comprising:

An acquisition module is used to acquire a fracturing operation task table of a target operation area; wherein the target operation area includes a plurality of fracturing operation sub-areas, each of the fracturing operation sub-areas has a plurality of fracturing operation points, and the fracturing operation task table includes a fracturing operation task of each fracturing operation point in a target period;

A determination module, used to determine the fracturing flowback fluid processing information of each fracturing operation point based on the fracturing operation task;

The first generation module is used to generate a fracturing flowback fluid processing task for each fracturing operation sub-area according to the fracturing flowback fluid processing information of each fracturing operation point;

The second generation module is used to obtain the state information of the fracturing flowback fluid reuse pool network, and generate a fracturing flowback fluid processing control instruction according to the state information and the fracturing flowback fluid processing task;

The execution module is used to send the fracturing return fluid processing control instruction to the fracturing return fluid buffer scheduling device and the fracturing return fluid processing device, and respectively execute the fracturing return fluid scheduling action and the fracturing return fluid processing action to complete the fracturing return fluid processing in the target operation area.

In addition, in order to achieve the above-mentioned purpose, the present invention also provides an oil and gas field fracturing return fluid processing control device, and the oil and gas field fracturing return fluid processing control device includes: a memory, a processor, and an oil and gas field fracturing return fluid processing control program stored in the memory and executable on the processor, and when the oil and gas field fracturing return fluid processing control program is executed by the processor, the steps of the oil and gas field fracturing return fluid processing control method as described above are implemented.

In addition, in order to achieve the above-mentioned purpose, the present invention also provides a storage medium, on which is stored an oil and gas field fracturing return fluid processing control program, and when the oil and gas field fracturing return fluid processing control program is executed by the processor, the steps of the above-mentioned oil and gas field fracturing return fluid processing control method are implemented.

The beneficial effects of the present invention are as follows: a method, device, equipment and storage medium for controlling the processing of fracturing return fluid in oil and gas fields are proposed, by obtaining the fracturing operation task of each fracturing operation point in each fracturing operation sub-area, generating the fracturing return fluid processing task of each fracturing operation sub-area, and then adjusting the fracturing return fluid processing speed of each fracturing operation sub-area and the call between different fracturing return fluid reuse pools by considering the state of the fracturing return fluid reuse pool network, thereby ensuring that each fracturing return fluid reuse pool is always within the range of the maximum buffer capacity, thereby ensuring that the fracturing operation point can continuously discharge and process the fracturing return fluid, and the fracturing operation tasks of multiple fracturing operation points can be executed on time, thereby improving the efficiency of fracturing return fluid processing, reducing the energy consumed in the processing process, and maximizing corporate benefits.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of a device structure of a hardware operating environment involved in an embodiment of the present invention;

FIG2 is a schematic flow chart of an embodiment of a method for controlling the treatment of oil and gas field fracturing flowback fluid according to the present invention;

FIG3 is a structural block diagram of an oil and gas field fracturing flowback fluid processing control device according to an embodiment of the present invention.

The realization of the purpose, functional features and advantages of the present invention will be further explained in conjunction with embodiments and with reference to the accompanying drawings.

DETAILED DESCRIPTION

It should be understood that the specific embodiments described herein are only used to explain the present invention, and are not used to limit the present invention.

In order to make the purpose, technical solution and advantages of the present invention more clearly understood, the present invention is further described in detail below in conjunction with the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to explain the present invention and are not intended to limit the present invention.

As shown in FIG. 1 , FIG. 1 is a schematic diagram of the device structure of the hardware operating environment involved in the embodiment of the present invention.

As shown in Figure 1, the device may include: a processor 1001, such as a CPU, a communication bus 1002, a user interface 1003, a network interface 1004, and a memory 1005. Among them, the communication bus 1002 is used to realize the connection and communication between these components. The user interface 1003 may include a display screen (Display), an input unit such as a keyboard (Keyboard), and the optional user interface 1003 may also include a standard wired interface and a wireless interface. The network interface 1004 may optionally include a standard wired interface and a wireless interface (such as a WI-FI interface). The memory 1005 may be a high-speed RAM memory, or a stable memory (non-volatile memory), such as a disk memory. The memory 1005 may also be a storage device independent of the aforementioned processor 1001.

Those skilled in the art will appreciate that the structure of the device shown in FIG. 1 does not limit the device, and may include more or fewer components than shown, or a combination of certain components, or a different arrangement of components.

As shown in FIG. 1 , the memory 1005 as a computer storage medium may include an operating system, a network communication module, a user interface module, and an oil and gas field fracturing flowback fluid processing control program.

In the terminal shown in FIG1 , the network interface 1004 is mainly used to connect to the backend server and perform data communication with the backend server; the user interface 1003 is mainly used to connect to the client (user end) and perform data communication with the client; and the processor 1001 can be used to call the oil and gas field fracturing return fluid processing control program stored in the memory 1005 and perform the following operations:

Acquire a fracturing operation task table of a target operation area; wherein the target operation area includes a plurality of fracturing operation sub-areas, each of the fracturing operation sub-areas has a plurality of fracturing operation points, and the fracturing operation task table includes a fracturing operation task of each fracturing operation point in a target period;

Based on the fracturing operation task, determining fracturing flowback fluid processing information for each fracturing operation point;

Generate a fracturing flowback fluid treatment task for each fracturing operation sub-area based on the fracturing flowback fluid treatment information of each fracturing operation point;

Acquire status information of a fracturing flowback fluid reuse pool network, and generate a fracturing flowback fluid processing control instruction according to the status information and the fracturing flowback fluid processing task;

The fracturing flowback fluid processing control instruction is sent to the fracturing flowback fluid buffer scheduling device and the fracturing flowback fluid processing device, and the fracturing flowback fluid scheduling action and the fracturing flowback fluid processing action are respectively executed to complete the fracturing flowback fluid processing in the target operation area.

The specific embodiments of the present invention applied to the device are basically the same as the embodiments of the following oil and gas field fracturing flowback fluid treatment control method, and will not be described in detail here.

An embodiment of the present invention provides a method for controlling the treatment of oil and gas field fracturing flowback fluid. Referring to FIG. 2 , FIG. 2 is a schematic flow chart of an embodiment of the method for controlling the treatment of oil and gas field fracturing flowback fluid of the present invention.

In this embodiment, the oil and gas field fracturing flowback fluid processing control method includes the following steps:

S100: Acquire a fracturing operation task table of a target operation area; wherein the target operation area includes a plurality of fracturing operation sub-areas, each of the fracturing operation sub-areas has a plurality of fracturing operation points, and the fracturing operation task table includes a fracturing operation task of each fracturing operation point in a target period;

S200: Determine fracturing flowback fluid processing information of each fracturing operation point based on the fracturing operation task;

S300: generating a fracturing flowback fluid processing task for each fracturing operation sub-area according to the fracturing flowback fluid processing information of each fracturing operation point;

S400: Acquire the status information of the fracturing flowback fluid reuse pool network, and generate a fracturing flowback fluid processing control instruction according to the status information and the fracturing flowback fluid processing task;

S500: Send the fracturing flowback fluid processing control instruction to the fracturing flowback fluid buffer scheduling device and the fracturing flowback fluid processing device, respectively executing the fracturing flowback fluid scheduling action and the fracturing flowback fluid processing action to complete the fracturing flowback fluid processing in the target operation area.

It should be noted that, at present, the main problem with the treatment of fracturing return fluid is the insufficient number of fracturing return fluid treatment equipment (cost and site limitations). Therefore, in actual engineering applications, a treatment method is usually adopted in which several fracturing operation points use a group of fracturing return fluid treatment equipment. Although this solves the problem of insufficient quantity very well, it also leads to the need for coordination of fracturing return fluid treatment tasks with very high accuracy among multiple fracturing operation points. Otherwise, it will affect the fracturing operation tasks of multiple fracturing operation points and affect the production progress of the enterprise. In order to solve the above problems, this embodiment obtains the fracturing operation tasks of each fracturing operation point in each fracturing operation sub-area, generates the fracturing return fluid processing tasks of each fracturing operation sub-area, and then adjusts the fracturing return fluid processing speed of each fracturing operation sub-area and the calls between different fracturing return fluid reuse pools by considering the state of the fracturing return fluid reuse pool network. In this way, it is ensured that each fracturing return fluid reuse pool is always within the range of the maximum buffer capacity, thereby ensuring that the fracturing operation point can continuously discharge and process the fracturing return fluid, and the fracturing operation tasks of multiple fracturing operation points can be executed on time, thereby improving the efficiency of fracturing return fluid treatment, reducing the energy consumed in the treatment process, and maximizing corporate benefits.

In a preferred embodiment, the step of obtaining the fracturing operation task table of the target operation area specifically includes: accessing the fracturing operation task database to extract the fracturing operation tasks that are assigned to each fracturing operation point and need to be performed within the target time period; calling the comparison relationship table between the fracturing operation point and the fracturing return fluid reuse pool to obtain the fracturing return fluid reuse pool corresponding to each fracturing operation point, and treating several fracturing operation points that use the same fracturing return fluid reuse pool as fracturing operation points in the same fracturing operation sub-area.

In this embodiment, by accessing the fracturing operation task database, the fracturing operation tasks of each fracturing operation point in the target time period that are pre-formulated and issued are queried, and according to the relationship between the fracturing operation point and the fracturing return fluid reuse pool, several fracturing operation points using the same fracturing return fluid reuse pool are regarded as fracturing operation points of the same fracturing operation sub-area, and finally several fracturing operation sub-areas are obtained, thereby controlling and coordinating the fracturing return fluid treatment for each fracturing operation sub-area.

In a preferred embodiment, based on the fracturing operation task, the step of determining the fracturing return fluid processing information of each fracturing operation point specifically includes: extracting the fracturing operation parameters in the fracturing operation task; wherein the fracturing operation parameters include the fracturing operation time and the fracturing fluid usage; querying the fracturing return rate corresponding to each fracturing operation point in the current operation stage, and generating the fracturing return fluid discharge volume of each fracturing operation point at each moment in the target time period according to the fracturing operation time, the fracturing fluid usage and the fracturing return rate; generating the fracturing return fluid processing information of each fracturing operation point according to the timestamp information at each moment and the corresponding fracturing return fluid discharge volume.

In this embodiment, the fracturing operation parameters include the fracturing operation time and the amount of fracturing fluid used. Then, according to the fracturing flowback rate of the current operation stage, the discharge amount of fracturing flowback fluid at each fracturing operation point at each moment can be calculated.

In a preferred embodiment, based on the fracturing flowback fluid processing information of each fracturing operation point, the fracturing flowback fluid processing task steps for each fracturing operation sub-area are generated, specifically including: calculating the total amount of fracturing flowback fluid discharged from each fracturing operation sub-area at each moment according to the fracturing flowback fluid discharge volume of each fracturing operation point at each moment; and using the total amount of fracturing flowback fluid discharged at each moment as the fracturing flowback fluid processing task of the fracturing flowback fluid reuse pool corresponding to each fracturing operation sub-area.

In this embodiment, the discharge volumes of fracturing flowback fluid from several fracturing operation points in a fracturing operation sub-area are summed up to obtain the total discharge volume of fracturing flowback fluid in each fracturing operation sub-area at each moment, thereby controlling and coordinating the fracturing flowback fluid treatment for each fracturing operation sub-area.

In a preferred embodiment, the status information of the fracturing return fluid reuse pool network is obtained, and the steps of generating a fracturing return fluid processing control instruction are generated according to the status information and the fracturing return fluid processing task, which specifically include: obtaining the status information of the fracturing return fluid reuse pool network; wherein the fracturing return fluid reuse pool network includes a plurality of fracturing return fluid reuse pools corresponding to each fracturing operation sub-area respectively, and the status information includes the connection relationship between any two fracturing return fluid reuse pools and the fracturing return fluid buffer volume of each fracturing return fluid reuse pool; extracting the total amount of fracturing return fluid discharged from each fracturing operation sub-area at each moment in the fracturing return fluid processing task, and generating a fracturing return fluid processing control instruction according to the relationship between the sum of the total amount of fracturing return fluid discharged and the fracturing return fluid buffer volume and the buffer volume upper limit of each fracturing return fluid reuse pool; wherein the fracturing return fluid processing control instruction includes a fracturing return fluid buffer scheduling instruction and a fracturing return fluid processing instruction.

In this embodiment, the status information of the fracturing return fluid reuse pool network includes the connection relationship between any two fracturing return fluid reuse pools (for example, reuse pool A is connected with reuse pools B, C, and D and can schedule fracturing return fluid with each other) and the fracturing return fluid buffer capacity of each fracturing return fluid reuse pool (that is, the fracturing return fluid buffer capacity of each fracturing return fluid reuse pool at the beginning of the target time period). Therefore, according to the connection relationship and the fracturing return fluid buffer capacity, fracturing return fluid buffer scheduling instructions and fracturing return fluid processing instructions can be generated to achieve the adjustment of the fracturing return fluid processing speed and scheduling of each fracturing return fluid reuse pool, thereby ensuring that each fracturing return fluid reuse pool is below the buffer capacity upper limit and does not affect the execution of fracturing operation tasks by the fracturing operation point connected to the fracturing return fluid reuse pool.

In a preferred embodiment, according to the relationship between the total amount of fracturing return fluid discharged, the sum of the fracturing return fluid buffer volume and the buffer volume upper limit of each fracturing return fluid reuse pool, a fracturing return fluid processing control instruction step is generated, which specifically includes: according to the relationship between the total amount of fracturing return fluid discharged, the sum of the fracturing return fluid buffer volume and the buffer volume upper limit of each fracturing return fluid reuse pool at each moment, adjusting the fracturing return fluid processing speed of the fracturing return fluid processing equipment corresponding to each moment; based on the fracturing return fluid processing speed, generating a fracturing return fluid processing control instruction for controlling the processing speed of the fracturing return fluid processing equipment; wherein, the fracturing return fluid processing control instruction includes a first control instruction for controlling a solid-liquid separation equipment and a second control instruction for controlling an aeration equipment; wherein, the first control instruction is configured to control the access usage ratio of a filtration equipment and a filter press equipment, and the second control instruction is configured to control the pump gas power level of an aeration equipment.

In this embodiment, the adjustment of the fracturing return fluid processing speed of each fracturing return fluid reuse pool is mainly achieved by controlling the equipment that can significantly reduce the processing time (such as filtering equipment and aeration equipment, etc., using different equipment access and different equipment power) to control the overall processing speed of the fracturing return fluid, and finally the most appropriate fracturing return fluid processing control instructions are determined based on the fracturing return fluid processing speed that meets each fracturing operation sub-area.

In a preferred embodiment, according to the relationship between the sum of the total discharge amount of the fracturing return fluid and the fracturing return fluid buffer amount at each moment and the buffer amount upper limit of each fracturing return fluid reuse pool, the step of adjusting the fracturing return fluid processing speed of the fracturing return fluid processing equipment corresponding to each moment specifically includes: judging whether there is a fracturing return fluid buffer amount obtained by subtracting the sum of the fracturing return fluid standard processing speeds at each moment before the target moment from the sum of the total discharge amount of the fracturing return fluid and the fracturing return fluid buffer amount calculated at the target moment, which exceeds the buffer amount upper limit; if so, adjusting the fracturing return fluid processing control instruction so that the sum of the power at each moment in the target time period is greater than that before the adjustment, and re-executing the above-mentioned judging step until There is no fracturing return fluid buffer volume at the target moment that exceeds the buffer volume upper limit, and the fracturing return fluid standard processing speed corresponding to the current fracturing return fluid processing control instruction is used as the fracturing return fluid processing speed of the fracturing return fluid processing equipment in the final target time period; if the sum of the powers at each moment in the target time period has been adjusted to the maximum, and there is still a fracturing return fluid buffer volume at the target moment that exceeds the buffer volume upper limit, then according to the connection relationship between the fracturing return fluid reuse pools, a third control instruction for controlling the fracturing return fluid buffer scheduling device is generated; according to the third control instruction, the fracturing return fluid buffer volume of the target fracturing return fluid reuse pool is dispatched to the adjacent fracturing return fluid reuse pool, and the above-mentioned judgment process is re-executed in the target fracturing return fluid reuse pool and the adjacent fracturing return fluid reuse pool until there is no situation in which the fracturing return fluid buffer volume at the target moment exceeds the buffer volume upper limit in each fracturing return fluid reuse pool.

In this embodiment, the method of adjusting the processing speed of the fracturing return fluid is: first, control the fracturing return fluid processing equipment with the lowest power to judge whether the processing speed satisfies the requirement that the buffer amount does not exceed the upper limit of the buffer amount at each moment; if it cannot be satisfied, then gradually increase the power until the fracturing return fluid processing speed with the buffer amount not exceeding the upper limit of the buffer amount and the lowest power is found, and then generate the corresponding first control instruction and second control instruction. It should be noted that if the power is still not met when it is increased to the maximum, it is necessary to generate a third control instruction to control the fracturing return fluid cache scheduling equipment, and schedule the fracturing return fluid cache volume of the target fracturing return fluid reuse pool to the adjacent fracturing return fluid reuse pool, and then re-judgment the cache volume upper limit judgment process of the target fracturing return fluid reuse pool and the adjacent fracturing return fluid reuse pool, and finally, achieve the purpose of ensuring that each fracturing return fluid reuse pool is below the cache volume upper limit, and thereby generate the final first control instruction, second control instruction and third control instruction, to achieve the coordinated execution of the fracturing return fluid processing tasks corresponding to each fracturing operation sub-area, without affecting the execution of fracturing operation tasks by the fracturing operation point connected to the fracturing return fluid reuse pool.

In this embodiment, a method for controlling the processing of fracturing return fluid in an oil and gas field is provided. The method generates a fracturing return fluid processing task for each fracturing operation sub-area by acquiring the fracturing operation task of each fracturing operation point in each fracturing operation sub-area, and then adjusts the fracturing return fluid processing speed of each fracturing operation sub-area and the calls between different fracturing return fluid reuse pools by considering the state of the fracturing return fluid reuse pool network. In this way, it is ensured that each fracturing return fluid reuse pool is always within the range of the maximum buffer capacity, thereby ensuring that the fracturing operation point can continuously discharge and process the fracturing return fluid, and the fracturing operation tasks of multiple fracturing operation points can be executed on time, thereby improving the efficiency of fracturing return fluid processing, reducing the energy consumed in the processing process, and maximizing corporate benefits.

3 , which is a structural block diagram of an embodiment of an oil and gas field fracturing flowback fluid processing control device according to the present invention.

As shown in FIG3 , the oil and gas field fracturing flowback fluid processing control device proposed in the embodiment of the present invention includes:

The acquisition module 10 is used to acquire a fracturing operation task table of a target operation area; wherein the target operation area includes a plurality of fracturing operation sub-areas, each of the fracturing operation sub-areas has a plurality of fracturing operation points, and the fracturing operation task table includes a fracturing operation task of each fracturing operation point in a target period;

A determination module 20, for determining fracturing flowback fluid processing information of each fracturing operation point based on the fracturing operation task;

The first generating module 30 is used to generate a fracturing flowback fluid processing task for each fracturing operation sub-area according to the fracturing flowback fluid processing information of each fracturing operation point;

The second generation module 40 is used to obtain the state information of the fracturing flowback fluid reuse pool network, and generate a fracturing flowback fluid processing control instruction according to the state information and the fracturing flowback fluid processing task;

The execution module 50 is used to send the fracturing return fluid processing control instruction to the fracturing return fluid buffer scheduling device and the fracturing return fluid processing device, respectively executing the fracturing return fluid scheduling action and the fracturing return fluid processing action to complete the fracturing return fluid processing in the target operation area.

Other embodiments or specific implementations of the oil and gas field fracturing flowback fluid processing control device of the present invention can refer to the above-mentioned method embodiments, which will not be described in detail here.

In addition, the present invention also proposes an oil and gas field fracturing return fluid processing control device, which includes: a memory, a processor, and an oil and gas field fracturing return fluid processing control program stored in the memory and executable on the processor, and when the oil and gas field fracturing return fluid processing control program is executed by the processor, the steps of the oil and gas field fracturing return fluid processing control method as described above are implemented.

The specific implementation of the oil and gas field fracturing flowback fluid processing control equipment of the present application is basically the same as the various embodiments of the above-mentioned oil and gas field fracturing flowback fluid processing control method, and will not be repeated here.

In addition, the present invention also proposes a readable storage medium, the readable storage medium includes a computer-readable storage medium, on which an oil and gas field fracturing return fluid processing control program is stored. The readable storage medium can be the memory 1005 in the terminal of Figure 1, or it can be at least one of ROM (Read-Only Memory)/RAM (Random Access Memory), a magnetic disk, and an optical disk. The readable storage medium includes a number of instructions for enabling an oil and gas field fracturing return fluid processing control device with a processor to execute the oil and gas field fracturing return fluid processing control method described in each embodiment of the present invention.

The specific implementation methods in the readable storage medium of the present application are basically the same as the various embodiments of the above-mentioned oil and gas field fracturing flowback fluid processing control method, and will not be repeated here.

It is understood that, in the description of this specification, the description with reference to the terms "one embodiment", "another embodiment", "other embodiments", or "first to Nth embodiments" etc. means that the specific features, structures, materials or characteristics described in conjunction with the embodiment or example are included in at least one embodiment or example of the present invention. In this specification, the schematic representation of the above terms does not necessarily refer to the same embodiment or example. Moreover, the specific features, structures, materials or characteristics described may be combined in any one or more embodiments or examples in a suitable manner.

It should be noted that, in this article, the terms "include", "comprises" or any other variations thereof are intended to cover non-exclusive inclusion, so that a process, method, article or system including a series of elements includes not only those elements, but also other elements not explicitly listed, or also includes elements inherent to such process, method, article or system. In the absence of further restrictions, an element defined by the sentence "comprises a ..." does not exclude the existence of other identical elements in the process, method, article or system including the element.

The serial numbers of the above embodiments of the present invention are only for description and do not represent the advantages or disadvantages of the embodiments.

Through the description of the above implementation methods, those skilled in the art can clearly understand that the above-mentioned embodiment methods can be implemented by means of software plus a necessary general hardware platform, and of course by hardware, but in many cases the former is a better implementation method. Based on such an understanding, the technical solution of the present invention is essentially or the part that contributes to the prior art can be embodied in the form of a software product, which is stored in a storage medium (such as ROM/RAM, magnetic disk, optical disk) as described above, and includes a number of instructions for a terminal device (which can be a mobile phone, computer, server, air conditioner, or network device, etc.) to execute the methods described in each embodiment of the present invention.

The above are only preferred embodiments of the present invention, and are not intended to limit the patent scope of the present invention. Any equivalent structure or equivalent process transformation made using the contents of the present invention specification and drawings, or directly or indirectly applied in other related technical fields, are also included in the patent protection scope of the present invention.

Claims (10)

1. A method for controlling the treatment of oil and gas field fracturing flowback fluid, characterized in that the method comprises the following steps: Acquire a fracturing operation task table of a target operation area; wherein the target operation area includes a plurality of fracturing operation sub-areas, each of the fracturing operation sub-areas has a plurality of fracturing operation points, and the fracturing operation task table includes a fracturing operation task of each fracturing operation point in a target period; Based on the fracturing operation task, determining fracturing flowback fluid processing information for each fracturing operation point; Generate a fracturing flowback fluid treatment task for each fracturing operation sub-area based on the fracturing flowback fluid treatment information of each fracturing operation point; Acquire status information of a fracturing flowback fluid reuse pool network, and generate a fracturing flowback fluid processing control instruction according to the status information and the fracturing flowback fluid processing task; The fracturing flowback fluid processing control instruction is sent to the fracturing flowback fluid buffer scheduling device and the fracturing flowback fluid processing device, and the fracturing flowback fluid scheduling action and the fracturing flowback fluid processing action are respectively executed to complete the fracturing flowback fluid processing in the target operation area. 2. The oil and gas field fracturing flowback fluid processing control method according to claim 1, characterized in that the step of obtaining the fracturing operation task list of the target operation area specifically includes: Accessing a fracturing operation task database, and extracting the fracturing operation tasks that are assigned to each fracturing operation point and need to be performed within a target period; The comparison relationship table between the fracturing operation points and the fracturing flowback fluid reuse pool is called to obtain the fracturing flowback fluid reuse pool corresponding to each fracturing operation point, and several fracturing operation points using the same fracturing flowback fluid reuse pool are regarded as fracturing operation points in the same fracturing operation sub-area. 3. The oil and gas field fracturing flowback fluid processing control method according to claim 1, characterized in that the step of determining the fracturing flowback fluid processing information of each fracturing operation point based on the fracturing operation task specifically includes: Extracting fracturing operation parameters in the fracturing operation task; wherein the fracturing operation parameters include fracturing operation time and fracturing fluid usage; Query the corresponding fracturing flowback rate of each fracturing operation point in the current operation stage, and generate the fracturing flowback fluid discharge volume of each fracturing operation point at each moment in the target time period according to the fracturing operation time, the fracturing fluid usage and the fracturing flowback rate; According to the timestamp information at each moment and the corresponding fracturing flowback fluid discharge volume, the fracturing flowback fluid processing information of each fracturing operation point is generated. 4. The oil and gas field fracturing flowback fluid processing control method according to claim 3 is characterized in that, according to the fracturing flowback fluid processing information of each fracturing operation point, the fracturing flowback fluid processing task steps of each fracturing operation sub-area are generated, specifically including: According to the discharge volume of fracturing flowback fluid at each fracturing operation point at each moment, the total discharge volume of fracturing flowback fluid at each fracturing operation sub-area at each moment is calculated; The total amount of the fracturing flowback fluid discharged at each moment is used as the fracturing flowback fluid processing task of the fracturing flowback fluid reuse pool corresponding to each fracturing operation sub-area. 5. The oil and gas field fracturing flowback fluid processing control method according to claim 4, characterized in that the state information of the fracturing flowback fluid reuse pool network is obtained, and the fracturing flowback fluid processing control instruction step is generated according to the state information and the fracturing flowback fluid processing task, specifically comprising: Acquire status information of a fracturing flowback fluid recycling pool network; wherein the fracturing flowback fluid recycling pool network includes a plurality of fracturing flowback fluid recycling pools corresponding to each fracturing operation sub-area, and the status information includes a connection relationship between any two fracturing flowback fluid recycling pools and a fracturing flowback fluid buffer volume of each fracturing flowback fluid recycling pool; The total amount of fracturing flowback fluid discharged at each moment in each fracturing operation sub-area in the fracturing flowback fluid processing task is extracted, and a fracturing flowback fluid processing control instruction is generated according to the relationship between the sum of the total amount of fracturing flowback fluid discharged and the fracturing flowback fluid buffer amount and the buffer amount upper limit of each fracturing flowback fluid reuse pool; wherein the fracturing flowback fluid processing control instruction includes a fracturing flowback fluid buffer scheduling instruction and a fracturing flowback fluid processing instruction. 6. The oil and gas field fracturing flowback fluid processing control method according to claim 5, characterized in that the fracturing flowback fluid processing control instruction step is generated according to the relationship between the sum of the total discharge amount of the fracturing flowback fluid and the fracturing flowback fluid buffer amount and the buffer amount upper limit of each fracturing flowback fluid reuse pool, specifically comprising: According to the relationship between the sum of the total discharge amount of the fracturing flowback fluid and the buffer amount of the fracturing flowback fluid at each moment and the buffer amount upper limit of each fracturing flowback fluid reuse pool, the fracturing flowback fluid processing speed of the fracturing flowback fluid processing equipment corresponding to each moment is adjusted; Based on the fracturing flowback fluid processing speed, generating a fracturing flowback fluid processing control instruction for controlling the processing speed of a fracturing flowback fluid processing device; Wherein, the fracturing flowback fluid processing control instruction includes a first control instruction for controlling a solid-liquid separation device and a second control instruction for controlling an aeration device; The first control instruction is configured to control the access usage ratio of the filtering device and the filter pressing device, and the second control instruction is configured to control the pump gas power level of the aeration device. 7. The oil and gas field fracturing flowback fluid processing control method according to claim 6, characterized in that the step of adjusting the fracturing flowback fluid processing speed of the fracturing flowback fluid processing equipment corresponding to each moment according to the relationship between the sum of the total amount of the fracturing flowback fluid discharged at each moment and the fracturing flowback fluid buffer volume and the buffer volume upper limit of each fracturing flowback fluid reuse pool specifically includes: Determine whether, during the process of executing the fracturing flowback fluid treatment in the target period at the fracturing flowback fluid standard treatment speed corresponding to the fracturing flowback fluid treatment control instruction with the lowest power at each moment within the target period, there is a fracturing flowback fluid buffer volume obtained by subtracting the sum of the fracturing flowback fluid standard treatment speeds at each moment before the target moment from the sum of the total discharge volume of the fracturing flowback fluid calculated at the target moment and the fracturing flowback fluid buffer volume, which exceeds the buffer volume upper limit; If so, adjust the fracturing flowback fluid processing control instruction so that the sum of the powers at each moment in the target time period is greater than that before the adjustment, re-execute the above-mentioned judgment step until there is no fracturing flowback fluid buffer volume exceeding the buffer volume upper limit at the target moment, and use the fracturing flowback fluid standard processing speed corresponding to the current fracturing flowback fluid processing control instruction as the fracturing flowback fluid processing speed of the fracturing flowback fluid processing equipment in the final target time period; If the sum of the powers at each moment in the target time period has been adjusted to the maximum, and there is still a fracturing flowback fluid buffer volume at the target moment that exceeds the buffer volume upper limit, a third control instruction for controlling the fracturing flowback fluid buffer scheduling device is generated according to the connection relationship between the fracturing flowback fluid reuse pools; According to the third control instruction, the fracturing return fluid buffer volume of the target fracturing return fluid reuse pool is dispatched to the adjacent fracturing return fluid reuse pool, and the above-mentioned judgment process is re-executed in the target fracturing return fluid reuse pool and the adjacent fracturing return fluid reuse pool until the fracturing return fluid buffer volume in each fracturing return fluid reuse pool at the target time does not exceed the buffer volume upper limit. 8. An oil and gas field fracturing flowback fluid processing control device, characterized in that it is used to execute the oil and gas field fracturing flowback fluid processing control method according to any one of claims 1 to 7, comprising: An acquisition module is used to acquire a fracturing operation task table of a target operation area; wherein the target operation area includes a plurality of fracturing operation sub-areas, each of the fracturing operation sub-areas has a plurality of fracturing operation points, and the fracturing operation task table includes a fracturing operation task of each fracturing operation point in a target period; A determination module, used to determine the fracturing flowback fluid processing information of each fracturing operation point based on the fracturing operation task; The first generation module is used to generate a fracturing flowback fluid processing task for each fracturing operation sub-area according to the fracturing flowback fluid processing information of each fracturing operation point; The second generation module is used to obtain the state information of the fracturing flowback fluid reuse pool network, and generate a fracturing flowback fluid processing control instruction according to the state information and the fracturing flowback fluid processing task; The execution module is used to send the fracturing return fluid processing control instruction to the fracturing return fluid buffer scheduling device and the fracturing return fluid processing device, and respectively execute the fracturing return fluid scheduling action and the fracturing return fluid processing action to complete the fracturing return fluid processing in the target operation area. 9. An oil and gas field fracturing return fluid processing control device, characterized in that the oil and gas field fracturing return fluid processing control device comprises: a memory, a processor and an oil and gas field fracturing return fluid processing control program stored in the memory and executable on the processor, and when the oil and gas field fracturing return fluid processing control program is executed by the processor, the steps of the oil and gas field fracturing return fluid processing control method as described in any one of claims 1 to 7 are implemented. 10. A storage medium, characterized in that an oil and gas field fracturing flowback fluid processing control program is stored on the storage medium, and when the oil and gas field fracturing flowback fluid processing control program is executed by a processor, the steps of the oil and gas field fracturing flowback fluid processing control method as described in any one of claims 1 to 7 are implemented.