CN110735636A - Method and system for measuring and calculating equivalent boundary distance of reservoir of multi-layer commingled production well - Google Patents

Abstract

The invention provides a measuring and calculating method and a measuring and calculating system for equivalent boundary distances of multi-layer commingled production well reservoirs, belonging to the field of oil and gas field development.

Description

Method and system for measuring and calculating equivalent boundary distance of reservoir of multi-layer commingled production well

Technical Field

The invention relates to the field of oil and gas field development, in particular to a method and a system for measuring and calculating equivalent boundary distances of multi-layer commingled production well reservoirs.

Background

Due to the deposition and later-stage construction of the reservoirs, longitudinal heterogeneity exists among the physical properties of all the reservoirs of the commingled production well, and the distance of the boundaries of all the reservoirs is different. The existing commingled production well pressure analysis method considers that the boundary distances of all reservoirs of the multiple commingled production wells are the same, and does not consider the difference of the boundary distances of all layers of the commingled production wells.

In the process of implementing the invention, the inventor of the application finds that the scheme in the prior art cannot accurately express the vertical heterogeneity of the actually measured commingled gas well reservoir.

Disclosure of Invention

In order to solve or at least partially solve the technical problems, embodiments of the present invention provide a method and a system for measuring and calculating equivalent boundary distances of multi-layer commingled production reservoirs.

The embodiment of the invention provides a method for measuring and calculating reservoir equivalent boundary distances of multi-layer commingled production wells, which comprises the steps of obtaining an actual measurement pressure value of an actual measurement bottom-hole pressure of the multi-layer commingled production well along with time change, simulating a theoretical pressure value of the theoretical bottom-hole pressure of the multi-layer commingled production well along with the time change according to a pre-configured seepage model, wherein the seepage model is pre-configured according to differences of all reservoir boundary distances of the multi-layer commingled production well and used for showing a corresponding relation between the theoretical bottom-hole pressure value and all reservoir boundary distances of the multi-layer commingled production well, calculating errors between the actual measurement pressure value and the theoretical pressure value corresponding to the same time, correcting the seepage model according to the errors to enable the errors to be within a preset error range, and measuring and calculating the equivalent boundary distances of the multi-layer commingled production well according to.

Preferably, the step of obtaining the actually measured pressure value of the actually measured bottom hole pressure of the multi-layer commingled production well along with the change of time comprises or more of the following steps of placing a pressure detection device at a well mouth of the multi-layer commingled production well, measuring the well mouth pressure value of the multi-layer commingled production well in real time after the well is shut down, calculating the actually measured bottom hole pressure value according to the well mouth pressure, placing the pressure detection device right above the multi-layer commingled production well, monitoring the bottom hole pressure value of the multi-layer commingled production well in real time after the well is shut down, placing the pressure detection device at the well mouth of the multi-layer commingled production well, measuring the well mouth pressure of the multi-layer commingled production well under the condition that.

Preferably, the pre-configuring the seepage model according to the difference of the reservoir boundary distances of the multi-layer commingled production well comprises: separating the respective reservoir boundaries by a distance r_ejIs configured to:

constructing the seepage model according to the configured boundary distances of the reservoirs, wherein the seepage model is represented by the following formula:

wherein r is_ejReservoir distance at jth layer; k is a radical of_jPermeability of the jth layer;

porosity of the jth layer; c_tjThe comprehensive compression coefficient of the j layer; h is_jIs the thickness of the jth layer; p_jIs the pressure of the j-th layer; j is the sequence number of the commingled production well reservoir, and j is 1,2,3 … n; p is a radical of_wBottom hole pressure; q is the yield of the multi-layer combined production well; μ is the fluid year; b is the fluid isothermal volume coefficient; r is_wIs the wellbore radius.

Preferably, the calculating the equivalent boundary distance of the multi-layer commingled production well according to the corrected seepage model comprises: calculating the boundary distance of each reservoir of the multi-layer commingled production well according to the corrected seepage model and the theoretical pressure value; and calculating the equivalent distance of the reservoir boundary of the commingled production well by using the equivalent seepage volume according to the boundary distance of each reservoir.

Correspondingly, the invention provides a measuring and calculating system for equivalent boundary distances of multi-layer commingled production well reservoirs, which comprises an obtaining module, a simulation module, a correction module and a measuring and calculating module, wherein the obtaining module is used for obtaining an actual measurement pressure value of an actual measurement bottom pressure of the multi-layer commingled production well along with time, the simulation module is used for simulating a theoretical pressure value of a theoretical bottom pressure of the multi-layer commingled production well along with time according to a pre-configured seepage model, the seepage model is pre-configured according to differences of boundary distances of all reservoirs of the multi-layer commingled production well and is used for showing a corresponding relation between the theoretical bottom pressure and all the reservoir boundary distances of the multi-layer commingled production well, the correction module is used for calculating errors between the actual measurement pressure value and the theoretical pressure value corresponding to the same time and correcting the constructed seepage model according to the errors so that the errors are within a preset error range, and the measuring and calculating module is used for measuring and calculating the equivalent boundary distances of the multi-layer commingled production well according to.

Preferably, the obtaining module comprises a pressure detecting device, and the pressure detecting device adopts or more of the following to obtain the actually measured pressure value of the actually measured bottom hole pressure along with the change of time, the pressure detecting device is arranged at the wellhead of the multilayer combined production well, the wellhead pressure value of the multilayer combined production well obtained after shut-in is obtained in real time, the actually measured bottom hole pressure value is calculated according to the wellhead pressure, the pressure detecting device is arranged right above the multilayer combined production well, the bottom hole pressure value of the multilayer combined production well obtained after shut-in is measured in real time, the pressure detecting device is arranged at the wellhead of the multilayer combined production well, the wellhead pressure value of the multilayer combined production well obtained under the condition that the wellhead is kept open is obtained in real time, and the actually measured bottom hole pressure value is calculated according to the wellhead pressure.

Preferably, the pressure detecting device is a pressure gauge.

Preferably, the simulation module includes: a configuration submodule for configuring said respective reservoir boundary distances r_ejIs configured to:

and the modeling submodule is used for constructing the seepage model shown as the following formula according to the configured boundary distance of each reservoir:

wherein r is_ejReservoir distance at jth layer; k is a radical of_jPermeability of the jth layer;

porosity of the jth layer; c_tjThe comprehensive compression coefficient of the j layer; h is_jIs the thickness of the jth layer; p_jIs the pressure of the j-th layer; j is the sequence number of the commingled production well reservoir, and j is 1,2,3 … n; p is a radical of_wBottom hole pressure; q is the yield of the multi-layer combined production well; μ is the fluid year; b is the fluid isothermal volume coefficient; r is_wIs the wellbore radius.

Preferably, the estimation module comprises: the layered measuring and calculating submodule is used for measuring and calculating the boundary distance of each reservoir of the multi-layer combined production well according to the corrected seepage model and the theoretical pressure value; and the equivalent measuring and calculating submodule is used for measuring and calculating the equivalent distance of the reservoir boundary of the commingled production well by using the equivalent seepage volume according to the boundary distance of each reservoir.

Accordingly, the embodiment of the present invention further provides machine-readable storage media, where the machine-readable storage media has instructions stored thereon, and the instructions are used for causing a machine to perform the method for calculating the equivalent boundary distance of the multi-layer commingled production reservoir described above in the present application.

Through the technical scheme, the seepage model is preconfigured according to the difference of the boundary distances of all reservoirs of the multi-layer commingled production well, the actual boundary distances of all the reservoirs are fully considered, so that the equivalent boundary distances of the multi-layer commingled production well are obtained through model construction, analysis and measurement.

Additional features and advantages of embodiments of the invention will be set forth in the detailed description which follows.

Drawings

The accompanying drawings are included to provide a further understanding of embodiments of the invention and are incorporated in and constitute a part of this specification , which together with the following detailed description serve to explain, but are not to limit, embodiments of the invention.

FIG. 1 is a flow chart of a method for measuring and calculating equivalent boundary distances of a multi-layer commingled production well reservoir provided by an embodiment of the invention;

FIG. 2 is a schematic diagram of a physical model of a multi-layer commingled production well seepage model provided by an embodiment of the invention;

FIG. 3 is a schematic diagram illustrating an error value between a measured pressure value and a theoretical pressure value corresponding to the same time according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of an equivalent seepage principle provided by an embodiment of the present invention;

FIG. 5 is a flowchart of an application example of the method for measuring and calculating the equivalent boundary distance of the multi-layer commingled production well reservoir provided by the embodiment of the invention;

FIG. 6 is a block diagram of a system for measuring and calculating equivalent boundary distances of a multi-layer commingled production well reservoir provided by an embodiment of the invention;

FIG. 7 is a block diagram of a simulation module provided by an embodiment of the present invention; and

fig. 8 is a block diagram of a measurement and calculation module according to an embodiment of the present invention.

Description of the reference numerals

1. Acquisition module 2 and simulation module

3. Correction module 4 and measuring and calculating module

21. Configuration submodule 22 and modeling submodule

41. Layered measurement and calculation submodule 42 and equivalent measurement and calculation submodule

Detailed Description

The following detailed description of embodiments of the invention refers to the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating embodiments of the invention, are given by way of illustration and explanation only, not limitation.

Fig. 1 is a flowchart of a method for calculating an equivalent boundary distance of a multi-layer commingled production well reservoir according to an embodiment of the present invention, and as shown in fig. 1, the method may include:

s100, obtaining an actually measured pressure value of the actually measured bottom hole pressure of the multi-layer combined production well along with time change.

In embodiments of the invention, the measured bottom hole pressure of the multi-layer commingled production well is obtained as a measured pressure value over time using or more of the following means:

1. and placing the pressure detection device at the wellhead of the multi-layer commingled production well, measuring the wellhead pressure value of the multi-layer commingled production well in real time after the well is closed, and calculating the actually measured bottom pressure value according to the wellhead pressure.

In view of the situations, in addition to the fact that the downhole accumulated liquid needs to be actually measured by the pressure gauge, the gas layer pressure and the bottom hole pressure of the dry gas well can be calculated according to the pressure measuring data of the wellhead.

For example, a pressure gauge is placed at a wellhead, wellhead pressure is obtained through real-time measurement after shut-in, bottom hole pressure is converted according to the wellhead pressure, and subsequent fitting calculation is performed after the wellhead pressure is converted into the bottom hole pressure by considering wellbore friction and liquid level height when the wellhead pressure is converted into the bottom hole pressure.

For example: the wellhead pressure measured by the pressure gauge is P_hThen bottom hole pressure P_w＝P_h+ ρ gh, where ρ represents the wellbore gas density; g represents the gravitational acceleration; h represents the bottom hole depth.

2. And (3) placing the pressure detection device right above the multi-layer combined production well, and monitoring the bottom hole pressure value of the multi-layer combined production well in real time after closing the well.

In the embodiment of the invention, the most direct method for measuring the bottom hole pressure is to place a pressure gauge at the bottom of the well, and monitor the bottom hole pressure value of the multi-layer commingled production well in real time after the well is shut down.

For example, a pressure gauge can be put right above a commingled production layer of a multi-layer commingled production well, and the bottom hole pressure change value after the well is shut down is monitored in real time.

3. And placing the pressure detection device at the wellhead of the multi-layer commingled production well, measuring the wellhead pressure of the multi-layer commingled production well under the condition of keeping the wellhead open, and calculating the actually measured bottom hole pressure value according to the wellhead pressure.

Specifically, a pressure gauge may be placed at the wellhead of the multi-layer commingled production well, and the wellhead pressure change value may be measured while keeping the wellhead open, and converted to the bottom hole pressure.

In the embodiment of the present invention, of the above methods for measuring the bottom hole pressure value are usually selected, and in practical applications, of the methods may be selected according to needs, or other suitable methods for measuring the bottom hole pressure may also be selected, and two or more methods may also be selected to measure the bottom hole pressure respectively, and a weighted average value calculation is performed on the measured bottom hole pressure values, so as to improve the accuracy of the bottom hole pressure measurement.

S200, simulating theoretical pressure values of theoretical bottom hole pressure of the multi-layer commingled production well along with time change according to a pre-configured seepage model, wherein the seepage model is pre-configured according to differences of all reservoir boundary distances of the multi-layer commingled production well and used for showing corresponding relations between the theoretical bottom hole pressure values and all reservoir boundary distances of the multi-layer commingled production well.

Fig. 2 is a schematic diagram of a physical model of a multi-layer commingled production well seepage model provided by an embodiment of the present invention, and as shown in fig. 2, reservoir boundary distances of each commingled production layer of a multi-layer commingled production well are different, and the reservoirs are stored in different reservoirsLayer boundary distance r_ejIs configured to:according to the configured boundary distances of the reservoirs, a mathematical model corresponding to a physical model of the seepage model is constructed (without considering the reservoirs and the skin) as shown in the following formula (1):

wherein p is_wBottom hole pressure in MPa; q is the well production in m³D; μ is the fluid year in mPa · s; b is the fluid isothermal volume coefficient, unit m³/m³；r_wIs the wellbore radius in m; r is_ejReservoir distance at stratum j, in m; k is a radical of_jPermeability of the j-th layer, unit 10^-3μm²；

Porosity of the jth layer in unit%; c_tjIs the integrated compression coefficient of the j layer in MPa-¹；h_jIs the thickness of the jth layer, in m; p_jIs the pressure of the j-th layer in MPa; j is the sequence number of the commingled well reservoir, and j is 1,2,3 … n.

After the Laplace transform is carried out on the formula (1), a dimensionless mathematical model (without considering well storage and skin) in a pull-type space is obtained as follows:

wherein: coefficient of flow

Dimensionless; storage capacity factor

Dimensionless; dimensionless timeDimensionless; dimensionless pressure

Dimensionless; dimensionless distance

Dimensionless; u is a pull-type space variable and is dimensionless.

Solving equation (2) to obtain a dimensionless bottom hole pressure solution without considering well reservoir and skin

In formula (3):

dimensionless; i is₀Is a class modified Bessel function of 0 order, and has no dimension₀Is a modified Bessel function of the second class 0, dimensionless, A₁And B₁Is the unknown to be solved. To A₁And B₁ reasonable initial values are set, and then the theoretical bottom hole pressure value of the multi-layer commingled production well is calculated by using the set initial values.

The method comprises the steps of obtaining a dimensionless bottom hole pressure solution considering well storage and skin coefficients in a pull-type space by using a Du-Ha's principle and considering the influences of the well storage effect and the skin effect on the bottom hole pressure, and obtaining the dimensionless bottom hole pressure solution in a real number space by using a Stehfest numerical inversion method, thereby obtaining a theoretical pressure value of the theoretical bottom hole pressure of the multi-layer combined production well along with the change of time.

Specifically, on the basis of obtaining a bottom-hole pressure solution through calculation according to the seepage model, the influence of a shaft reservoir effect and a skin effect on the bottom-hole pressure is considered according to the Du-Hammet principle. For example: the whole multi-layer commingled production well system is divided into three parts, namely a shaft, a reservoir and a boundary: the well bore part considers the well bore storage effect when closing the well and is characterized by a well storage coefficient; the pressure drop loss from the shaft to the reservoir is characterized by a skin coefficient; reservoir to boundary commingled production well reservoir flow is characterized using the seepage model described above. Therefore, a more accurate theoretical pressure value of the theoretical bottom hole pressure of the multi-layer combined production well changing along with time is obtained.

S300, calculating an error between the actual measurement pressure value and the theoretical pressure value corresponding to the same time, and correcting the seepage model according to the error so that the error is within a preset error range.

In the embodiment of the present invention, an error between the actual measured pressure value and the theoretical pressure value corresponding to the same time is calculated by using a least square method (or other suitable neural network algorithm may be used for calculation, which is not limited by the present invention) according to the actual measured pressure value of the multi-layer commingled production well varying with time in step S100 and the theoretical pressure value of the theoretical bottom pressure of the multi-layer commingled production well simulated in step S200, and the set a is compared with the set a according to the calculated error₁And B₁The initial value of the multi-layer commingled production well is adjusted to correct the seepage model of the multi-layer commingled production well.

Specifically, reservoir basic physical parameters (such as the number of reservoir layers of a multi-layer co-production well, the thickness of each reservoir, the porosity, the comprehensive compressibility, the original formation pressure and the like) and initial fitting parameter values (set A) are given according to known reservoir information₁And B₁The initial values of the method comprise well storage coefficients, skin coefficients, permeability of each layer, boundary distance of each layer and the like of a multi-layer commingled production well), obtaining bottom hole pressure calculation results of the seepage model of the invention corresponding to the parameters, setting preset error values, calculating the error value between the bottom hole pressure and the actually measured bottom hole pressure of the seepage model of the invention by using a least square method, outputting fitting parameter results if the error between the bottom hole pressure and the actually measured bottom hole pressure is less than or equal to the preset error value, and otherwise, adjusting fitting parameters (A)₁And B₁) And recalculating the bottom hole pressure and judging the error value until the error value is less than or equal to the preset error value, stopping the repeated calculation and outputting a fitting parameter value.

In addition, A is₁And B₁Instead of individual physical or mathematical parameters in the conventional sense, a parameter matrix consisting of a plurality of parameters, such as well-reservoir coefficients, skin coefficients, permeability of each layer, boundary distance of each layer, etc., may be included, and adjusting any of the plurality of parameters in the matrix will affect A₁And B₁The value of (c). For set A₁And B₁The process of adjusting the initial value of (2) is a process of adjusting a plurality of parameters in the parameter matrix.

For example, fig. 3 is a schematic diagram of an error value between a measured pressure value and a theoretical pressure value corresponding to the same time according to the embodiment of the present invention, and as shown in fig. 3, the measured pressure value and the theoretical pressure value are fitted, and the fitting process substantially calculates an error between the measured pressure value and the theoretical pressure value corresponding to the same time, and adjusts the parameter matrix a according to the error₁And B₁The parameters are included so that the error is within a preset error range, thereby correcting the seepage model. The measured pressure values correspond to the pressures (test data) in FIG. 3, the theoretical pressure values correspond to the pressures (theoretical data) in FIG. 3, and the values are adjusted according to A₁And B₁When the fitting result of the theoretical pressure value calculated by the corrected seepage model and the actually measured pressure value obtained by actual measurement can achieve the fitting effect as shown in fig. 3, it indicates that a₁And B₁The setting is reasonable.

And S400, calculating the equivalent boundary distance of the multi-layer commingled production well according to the corrected seepage model.

In the embodiment of the invention, the boundary distance of each reservoir of the multi-layer commingled production well is measured and calculated according to the corrected seepage model and the theoretical pressure value; and calculating the equivalent distance of the reservoir boundary of the commingled production well by using the equivalent seepage volume according to the boundary distance of each reservoir.

Specifically, taking the equivalent Seepage principle diagram provided by the embodiment of the invention shown in fig. 4 as an example, defining equivalent Seepage volume ESV (equivalent drainage volume) according to the equal volume principle, wherein complex Seepage volumes (shown in fig. 4 a) can be replaced by the simplest Seepage volume (shown in fig. 4 b), and because of the non-unique nature of the equivalent Seepage volume, complex Seepage volumes can at least find simple ESVs, therefore, the actual reservoir of the multi-layer commingled production well can be reasonably explained by using various well test models without considering the geological data of the multi-layer commingled production well, and the equivalent boundary distance of the multi-layer commingled production well with the difference of the boundary distances of the multiple reservoirs can be calculated according to the following formula (4) according to the concept of ESVs:

wherein r is_MRepresenting the equivalent distance of the boundary of the multi-layer commingled production well; r is_jRepresenting the reservoir distance at the jth layer; h is_jRepresents the thickness of the j-th layer; phi is a_jIndicating the porosity of the j layer; k is a radical of_jRepresents the permeability of the j-th layer; j represents the sequence number of the commingled producing well reservoir, j is 1,2,3 … n; h is_tRepresenting the thickness of a reservoir corresponding to the bottom hole pressure at the current moment;

representing the average value of the porosity of each reservoir of the multi-layer commingled production well;

the average value of the permeability of each reservoir of the multi-layer commingled production well is shown.

And (4) obtaining the parameters of each co-production layer of the multi-layer co-production well in the formula (4) according to the fitting result of the constructed mathematical model of the seepage model to bottom hole pressure data.

And according to the equivalent seepage volume principle, calculating the equivalent distance of the reservoir boundary according to the basic physical parameters (such as the number of layers, the thickness of each layer, the porosity and the comprehensive compressibility) of each reservoir of the multi-layer combined production well and the final fitting parameters (including but not limited to the permeability of each layer and the boundary distance of each layer).

The method for calculating the equivalent boundary distance of the multi-layer commingled production well reservoir provided by the embodiment of the invention is illustrated by specific application examples.

Fig. 5 is a flowchart of an application example of the method for measuring and calculating the equivalent boundary distance of the multi-layer commingled production well reservoir according to the embodiment of the present invention, and as shown in fig. 5, the method may include the following steps:

s11, actually measuring the bottom hole pressure in various ways.

Specifically, the bottom hole pressure after the well is shut down is directly measured by a pressure gauge, or the bottom hole pressure is measured and converted into the bottom hole pressure to obtain the bottom hole pressure measured value. To plot a measured bottom hole pressure value curve.

S12, drawing an actually measured bottom hole pressure value curve P_t0＝f(t)。

Drawing an actually measured bottom hole pressure value curve P according to the bottom hole pressure actually measured in the step S11_t0＝f(t)。

S21, inputting initial fitting parameters M₀(C₀，S₀，k_j0，r_ej0) The number of reservoir layers of the multi-layer commingled production well and the original earth pressure p_jThickness of each reservoir h_jPorosity, degree of porosity

C_tjIs the integrated compression factor of the j-th layer.

Specifically, in a seepage model constructed in advance, initial fitting parameters are input to calculate a theoretical bottom hole pressure value, so that a theoretical bottom hole pressure value curve is drawn.

S22, calculating a theoretical bottom hole pressure value curve P according to the seepage model_t＝F(M₀,t)。

Drawing a theoretical bottom hole pressure value curve P according to the theoretical bottom hole pressure value obtained in the step S11_t＝F(M₀,t)。

And S3, fitting the actual bottom hole pressure value curve and the theoretical bottom hole pressure value curve.

And fitting the actual bottom hole pressure value curve obtained in the step S12 and the theoretical bottom hole pressure value curve obtained in the step S22.

S4, determining the result of the fitting of the actual and theoretical bottom hole pressure values in step S3, e.g.: judging whether the error between the actual bottom hole pressure value and the theoretical bottom hole pressure value meets the preset error requirement or not: | p_t-p_t0|<e, wherein e is a preset error value. If yes, go to step S42 directly; if not, go to step S41.

S41, fitting the parameter M, and re-assigning the value to M₀。

If the fitting result in step S4 does not satisfy the preset error requirement, it indicates that the fitting parameter M is not reasonable and needs to be reassigned to M₀And returns to execution of step S21.

S42, outputting fitting parameters M (C, S, k)_j，r_ej)。

If the fitting result in step S4 satisfies the preset error requirement, it indicates that the fitting parameter M is reasonable, and at this time, the fitting parameter M (C, S, k) is output_j，r_ej) And (4) finishing.

S5, according to ESV and r_ejAnd calculating the equivalent boundary distance of the multi-layer commingled production well.

Determining a seepage model according to the fitting parameters obtained in the step S42, thereby determining the boundary distance r of each layer of the multi-layer co-production layer_ejAnd calculating the equivalent boundary distance of the multi-layer commingled production well by using the equivalent seepage volume ESV.

Fig. 6 is a block diagram of a system for measuring and calculating an equivalent boundary distance of a multi-layer commingled production reservoir according to an embodiment of the present invention, and as shown in fig. 6, the system for measuring and calculating an equivalent boundary distance of a multi-layer commingled production reservoir includes: the system comprises an acquisition module 1, a data processing module and a data processing module, wherein the acquisition module is used for acquiring an actually measured pressure value of actually measured bottom hole pressure of a multi-layer combined production well along with time change; the simulation module 2 is used for simulating theoretical pressure values of theoretical bottom hole pressure of the multi-layer commingled production well changing along with time according to a pre-configured seepage model, wherein the seepage model is pre-configured according to differences of all reservoir boundary distances of the multi-layer commingled production well and used for showing a corresponding relation between the theoretical bottom hole pressure and all reservoir boundary distances of the multi-layer commingled production well; the correction module 3 is used for calculating an error between an actual measurement pressure value and a theoretical pressure value corresponding to the same time, and correcting the constructed seepage model according to the error so as to enable the error to be within a preset error range; and the measuring and calculating module 4 is used for measuring and calculating the equivalent boundary distance of the multi-layer combined production well according to the corrected seepage model.

The acquisition module 1 comprises a pressure detection device (not shown in the figure), wherein the pressure detection device acquires an actual measurement pressure value of the actual measurement bottom hole pressure along with time change by adopting or more of the following steps of placing the pressure detection device at the well mouth of the multilayer combined production well, acquiring the well mouth pressure value of the multilayer combined production well measured after closing the well in real time, calculating the actual measurement bottom hole pressure value according to the well mouth pressure, placing the pressure detection device right above the multilayer combined production well, measuring the bottom hole pressure value of the multilayer combined production well after closing the well in real time, placing the pressure detection device at the well mouth of the multilayer combined production well, acquiring the well mouth pressure value of the multilayer combined production well measured under the condition that the well mouth is kept open in real time, and calculating the actual measurement bottom hole pressure value according to the well mouth pressure.

Preferably, the pressure detecting means is a pressure gauge.

Fig. 7 is a block diagram of a simulation module according to an embodiment of the present invention, and as shown in fig. 7, the simulation module 2 includes: a configuration submodule 21 for assigning respective reservoir boundary distances r_ejIs configured to:

and a modeling submodule 22 for constructing a seepage model shown in the above formula (1) according to the configured boundary distances of the reservoirs.

Fig. 8 is a block diagram of a measurement and calculation module according to an embodiment of the present invention, and as shown in fig. 8, the measurement and calculation module 4 includes: the layered measuring and calculating submodule 41 is used for measuring and calculating the boundary distance of each reservoir of the multi-layer combined production well according to the corrected seepage model and the theoretical pressure value; and the equivalent measuring and calculating submodule 42 is used for measuring and calculating the equivalent distance of the reservoir boundary of the commingled production well by utilizing the equivalent seepage volume according to the boundary distance of each reservoir.

For other specific implementation details and beneficial effects of the system for measuring and calculating the equivalent boundary distance of the multi-layer commingled production well reservoir, reference is made to the method for measuring and calculating the equivalent boundary distance of the multi-layer commingled production well reservoir, and details are not repeated here.

Through the technical scheme, the seepage model is preconfigured according to the difference of the boundary distances of all reservoirs of the multi-layer commingled production well, the actual boundary distances of all the reservoirs are fully considered, so that the equivalent boundary distances of the multi-layer commingled production well are obtained through model construction, analysis and measurement.

The device for measuring and calculating the equivalent boundary distance of the multi-layer commingled production well reservoir comprises a processor and a memory, wherein the acquisition module, the simulation module, the correction module and the like are stored in the memory as program units, and the processor executes the program units stored in the memory to realize corresponding functions.

The processor comprises a kernel, and the kernel calls corresponding program units from the memory, wherein or more kernels can be set, and the equivalent boundary distance of the multi-layer commingled production reservoir can be measured and calculated by adjusting kernel parameters.

The memory may include volatile memory in a computer readable medium, Random Access Memory (RAM) and/or non-volatile memory such as Read Only Memory (ROM) or flash memory (flash RAM), including at least memory chips.

The embodiment of the invention provides storage media, wherein the storage media store programs, when being executed by a processor, the programs realize the method for measuring and calculating the equivalent boundary distance of the multi-layer commingled production well reservoir.

The embodiment of the invention provides processors, wherein the processors are used for running programs, and the programs are used for executing the method for measuring and calculating the equivalent boundary distance of the multilayer commingled production well reservoir when running.

Moreover, the present application may take the form of a computer program product embodied on or more computer-usable storage media (including but not limited to disk storage, CD-ROM, optical storage, etc.) having computer-usable program code embodied therein.

It is to be understood that each flow and/or block in the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions which can be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flow diagram flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

In typical configurations, a computing device includes or more processors (CPUs), input/output interfaces, network interfaces, and memory.

The memory may include forms of volatile memory in a computer readable medium, Random Access Memory (RAM) and/or non-volatile memory, such as Read Only Memory (ROM) or flash memory (flash RAM). The memory is an example of a computer-readable medium.

Computer-readable media, including both non-transitory and non-transitory, removable and non-removable media, may implement information storage by any method or technology. The information may be computer readable instructions, data structures, modules of a program, or other data. Examples of computer storage media include, but are not limited to, phase change memory (PRAM), Static Random Access Memory (SRAM), Dynamic Random Access Memory (DRAM), other types of Random Access Memory (RAM), Read Only Memory (ROM), Electrically Erasable Programmable Read Only Memory (EEPROM), flash memory or other memory technology, compact disc read only memory (CD-ROM), Digital Versatile Discs (DVD) or other optical storage, magnetic cassettes, magnetic tape magnetic disk storage or other magnetic storage devices, or any other non-transmission medium that can be used to store information that can be accessed by a computing device. As defined herein, a computer readable medium does not include a transitory computer readable medium such as a modulated data signal and a carrier wave.

It should also be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises the series of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The above are merely examples of the present application and are not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (10)

1, method for measuring and calculating equivalent boundary distance of multilayer commingled production well reservoir, characterized in that the method for measuring and calculating equivalent boundary distance of multilayer commingled production well reservoir comprises:

acquiring an actually measured pressure value of the actually measured bottom hole pressure of the multi-layer combined production well along with time change;

simulating a theoretical pressure value of the theoretical bottom hole pressure of the multi-layer commingled production well along with time change according to a pre-configured seepage model, wherein the seepage model is pre-configured according to the difference of each reservoir boundary distance of the multi-layer commingled production well and is used for showing the corresponding relation between the theoretical bottom hole pressure value and each reservoir boundary distance of the multi-layer commingled production well;

calculating an error between the actual measurement pressure value and the theoretical pressure value corresponding to the same time, and correcting the seepage model according to the error so as to enable the error to be within a preset error range; and

and calculating the equivalent boundary distance of the multi-layer commingled production well according to the corrected seepage model.

2. The method for measuring and calculating the equivalent boundary distance of the multi-layer commingled production well reservoir according to claim 1, wherein the obtaining of the measured pressure value of the measured bottom hole pressure of the multi-layer commingled production well, which changes along with the time, comprises or more of the following steps:

placing a pressure detection device at a wellhead of the multi-layer commingled production well, measuring a wellhead pressure value of the multi-layer commingled production well in real time after the well is shut down, and calculating an actually measured bottom pressure value according to the wellhead pressure;

placing a pressure detection device right above the multi-layer combined production well, and monitoring the bottom hole pressure value of the multi-layer combined production well in real time after closing the well; and

and placing a pressure detection device at the wellhead of the multi-layer commingled production well, measuring the wellhead pressure of the multi-layer commingled production well under the condition of keeping the wellhead open, and calculating the actually measured bottom hole pressure value according to the wellhead pressure.

3. The method for calculating reservoir equivalent boundary distances of a multi-layer commingled production well according to claim 1, wherein the pre-configuring of the seepage model according to the differences of the reservoir boundary distances of the multi-layer commingled production well comprises:

separating the respective reservoir boundaries by a distance r_ejIs configured to:

constructing the seepage model according to the configured boundary distances of the reservoirs, wherein the seepage model is represented by the following formula:

wherein r is_ejReservoir distance at jth layer; k is a radical of_jPermeability of the jth layer;

porosity of the jth layer; c_tjThe comprehensive compression coefficient of the j layer; h is_jIs the thickness of the jth layer; p_jIs the pressure of the j-th layer; j is the sequence number of the commingled production well reservoir, and j is 1,2,3 … n; p is a radical of_wBottom hole pressure; q is the yield of the multi-layer combined production well; μ is the fluid year; b is the fluid isothermal volume coefficient; r is_wIs the wellbore radius.

4. The method for calculating the equivalent boundary distance of the multi-layer commingled production well reservoir according to the claim 1, wherein the calculating the equivalent boundary distance of the multi-layer commingled production well according to the corrected seepage flow model comprises:

calculating the boundary distance of each reservoir of the multi-layer commingled production well according to the corrected seepage model and the theoretical pressure value; and

and calculating the equivalent distance of the reservoir boundary of the commingled production well by using the equivalent seepage volume according to the boundary distance of each reservoir.

The system for measuring and calculating the equivalent boundary distance of the multi-layer commingled production well reservoir is characterized by comprising the following steps of:

the acquisition module is used for acquiring an actually measured pressure value of the actually measured bottom hole pressure of the multi-layer combined production well along with time change;

the simulation module is used for simulating a theoretical pressure value of the theoretical bottom hole pressure of the multi-layer commingled production well along with time change according to a pre-configured seepage model, wherein the seepage model is pre-configured according to the difference of each reservoir boundary distance of the multi-layer commingled production well and used for showing the corresponding relation between the theoretical bottom hole pressure and each reservoir boundary distance of the multi-layer commingled production well;

the correction module is used for calculating the error between the actual measurement pressure value and the theoretical pressure value corresponding to the same time, and correcting the constructed seepage model according to the error so as to enable the error to be within a preset error range; and

and the measuring and calculating module is used for measuring and calculating the equivalent boundary distance of the multi-layer combined production well according to the corrected seepage model.

6. The system for measuring and calculating the equivalent boundary distance of a multi-layer commingled production reservoir of claim 5, wherein the obtaining module comprises a pressure detecting device, and the pressure detecting device obtains a measured pressure value of the measured bottom hole pressure along with time by using one or more of the following :

placing a pressure detection device at a wellhead of the multi-layer commingled production well, obtaining a wellhead pressure value of the multi-layer commingled production well measured after closing the well in real time, and calculating the actually measured bottom pressure value according to the wellhead pressure;

placing a pressure detection device right above the multi-layer combined production well, and measuring the bottom hole pressure value of the multi-layer combined production well after closing the well in real time; and

and arranging a pressure detection device at a wellhead of the multi-layer commingled production well, acquiring a wellhead pressure value of the multi-layer commingled production well measured under the condition of keeping the wellhead open in real time, and calculating the actually measured bottom pressure value according to the wellhead pressure.

7. The system for calculating the equivalent boundary distance of a multi-layer commingled production reservoir of claim 6, wherein the pressure detection device is a pressure gauge.

8. The system for calculating equivalent boundary distances of a multi-layer commingled production reservoir of claim 5, wherein the simulation module comprises:

a configuration submodule for configuring said respective reservoir boundary distances r_ejIs configured to:

and

the modeling submodule is used for constructing the seepage model shown as the following formula according to the configured boundary distance of each reservoir:

wherein r is_ejReservoir distance at jth layer; k is a radical of_jPermeability of the jth layer;porosity of the jth layer; c_tjThe comprehensive compression coefficient of the j layer; h is_jIs the thickness of the jth layer; p_jIs the pressure of the j-th layer; j is the sequence number of the commingled production well reservoir, and j is 1,2,3 … n; p is a radical of_wBottom hole pressure; q is the yield of the multi-layer combined production well; μ is the fluid year; b is the fluid isothermal volume coefficient; r is_wIs the wellbore radius.

9. The system for calculating equivalent boundary distances of a multi-layer commingled production reservoir of claim 5, wherein the calculation module comprises:

the layered measuring and calculating submodule is used for measuring and calculating the boundary distance of each reservoir of the multi-layer combined production well according to the corrected seepage model and the theoretical pressure value; and

and the equivalent measuring and calculating submodule is used for measuring and calculating the equivalent distance of the reservoir boundary of the commingled production well by using the equivalent seepage volume according to the boundary distance of each reservoir.

10, a machine-readable storage medium having instructions stored thereon for causing a machine to perform the method of estimating equivalent boundary distances for a multi-commingled production reservoir of any of claims 1-4 at .

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