CN109488284B - Simulation test device for water pressure propagation distance in drainage and production process of coal bed gas vertical well - Google Patents

Abstract

The invention discloses a device for simulating and testing the water pressure propagation distance in the drainage and production process of a coal bed gas vertical well, which comprises a vertical well drainage system and a plurality of groups of water pressure variable load systems; the vertical well drainage system comprises a base and supports, wherein the base is provided with simulation shafts, the number of the simulation shafts is equal to that of the hydraulic variable load system, each simulation shaft is internally connected with a pressurizing cylinder in a threaded sealing manner, the top of each support is provided with guide holes, the guide holes correspond to the simulation shafts one by one, and the pressurizing cylinders are arranged in the guide holes in a penetrating manner; each group of water pressure variable load system is correspondingly connected with the lower port of the simulation shaft through a water pressure transmission pipe penetrating through the base. The invention can monitor the permeability change in different directions in the coal bed gas vertical well drainage and production process; the method can monitor the water pressure propagation rule caused by permeability change in different directions in the drainage and production process of the coal bed gas well more truly, and can test the water pressure propagation distance more accurately under the conditions of different reservoir permeability and permeability change in the drainage and production process, so as to lay a foundation for accurately predicting the gas production of the coal bed gas vertical well.

Description

Simulation test device for water pressure propagation distance in drainage and production process of coal bed gas vertical well

Technical Field

The invention belongs to the technical field of coal bed gas drainage and production, and particularly relates to a device for simulating and testing the water pressure propagation distance in the drainage and production process of a coal bed gas vertical well.

Background

When the coal bed gas is developed on the ground, the coal bed gas is changed from an adsorption state to a free state in the coal bed by discharging and extracting water in the coal bed, which is a main reason for whether the gas can be desorbed and output. That is, if the water in the coal seam can not flow during drainage and mining, the space environment of the coal seam gas can not be changed, and the coal seam gas can not be changed from an adsorption state to a free state. The distance and range of water pressure propagation are different, and the gas desorption amount is also different, so that the premise of accurately predicting the gas production rate by finding out the water pressure propagation distance in the drainage and mining process is provided.

Differences in permeability of a coal reservoir, reservoir pressure, bottom hole pressure during drainage and production, water supply condition of surrounding rock, drainage and production time and the like cause different water pressure propagation distances in the drainage and production process. In order to find out influence factors and propagation distances of the water pressure propagation distances in the drainage and mining processes, some researchers combine Darcy's law to deduce a formula of the water pressure propagation distances based on a well testing principle, but the water pressure propagation distances caused by reservoir heterogeneity differences and permeability changes in the drainage and mining processes are not considered, so that the calculation results of the water pressure propagation distances have certain access to the actual water pressure propagation distances. And (3) calculating the water pressure propagation distance by adopting a well testing method, wherein when the heterogeneity difference in the longitudinal direction of the coal seam is small, the difference between the result and the actual result is not large. When the heterogeneity of the coal seam in the longitudinal direction is strong, namely the permeability difference in the longitudinal direction is large, the result represents the farthest propagation distance in the drainage and mining process, the water pressure propagation distance of the whole coal seam section cannot be accurately reflected, and the gas production of the coal seam section after guidance has great limitation. Some researchers adopt Esplase and Comet3.0 combined with Matlab software to simulate the water pressure propagation in the drainage and mining process, and can not accurately express the influence of reservoir heterogeneity and permeability change in the drainage and mining process on the water pressure propagation distance, and the simulation result has a certain access with the reality. Therefore, a set of testing device is urgently needed to be developed, and the water pressure propagation distance can be accurately tested under the conditions of different coal reservoir permeability, permeability change in the drainage and production process, bottom hole pressure, reservoir pressure and the like, so that the cicada gas quantity prediction of the coal-bed gas well can be better guided.

Disclosure of Invention

In order to overcome the defects in the prior art, the invention provides a device for simulating and testing the water pressure propagation distance in the drainage and production process of a coal bed gas vertical well; the device can carry out more accurate test to water pressure propagation distance under the condition of different reservoir permeability, the permeability change of the drainage and production process to lay a foundation for accurate prediction of the gas production of the coal bed gas vertical well.

In order to solve the technical problems, the invention adopts the following technical scheme: the device for simulating and testing the water pressure propagation distance in the drainage and production process of the coal bed gas vertical well comprises a vertical well drainage system and a plurality of groups of water pressure variable load systems, wherein the water pressure variable load systems are arranged around the vertical well drainage system; the vertical well drainage system comprises a base and a support, wherein simulation shafts equal to the hydraulic pressure variable load system in number are arranged on the base in the vertical direction, the lower end of the support is fixedly arranged on one side of the base, a pressurizing cylinder is connected in each simulation shaft in a threaded sealing manner, the upper end of the pressurizing cylinder is blocked, the lower end of the pressurizing cylinder is opened and communicated with the inside of the simulation shaft, guide holes corresponding to the simulation shafts one by one are formed in the top of the support, the pressurizing cylinders are arranged in the guide holes in a penetrating manner, the simulation shafts and the pressurizing cylinders are made of transparent materials, scales are arranged on the side parts of the simulation shafts in the axial direction, and the lower part of each simulation shaft is connected with a first pressure gauge; each group of water pressure variable load system is correspondingly connected with the lower port of the simulation shaft through a water pressure transmission pipe penetrating through the base.

Each group of water pressure variable-load systems comprises a first manual rocking plunger pump, a second manual rocking plunger pump, a vacuum pump, a water injection tank and a controllable variable-seepage device;

the controllable variable-permeability device comprises a mounting seat, a variable-permeability box in a cuboid shape is fixedly arranged on the mounting seat through a fixing bolt, an upper pressing plate and a lower pressing plate are horizontally arranged in the variable-permeability box, the inner parts of the variable-permeability box are divided into an upper pressurizing cavity, a middle-variable-permeability cavity and a lower pressurizing cavity from top to bottom, the peripheral outer walls of the upper pressing plate and the lower pressing plate are in sliding sealing connection with the periphery of the inner wall of the variable-permeability box, a variable-permeability material is filled in the middle-variable-permeability cavity formed between the upper pressing plate and the lower pressing plate in the variable-permeability box, an upper spring is arranged between the upper side surface of the upper pressing plate and the top of the variable-permeability box, a lower spring is arranged between the lower side surface of the lower pressing plate and the bottom of the variable-permeability box, a liquid injection port of the first hand-operated plunger pump is communicated with the outer side of the middle-variable-permeability cavity through a first liquid injection pipe, and the inner side of the middle-variable-permeability cavity is communicated through one end of a hydraulic transmission pipe;

the vacuum pump is respectively connected with the first liquid injection pipe and the water pressure transmission pipe through a first vacuum pipe and a second vacuum pipe, and the first vacuum pipe and the second vacuum pipe are respectively provided with a first valve;

a second pressure gauge is arranged on the first hand-cranking plunger pump, a liquid inlet of the first hand-cranking plunger pump is connected with the water injection tank through a first liquid pumping pipe, and a second valve is arranged on the first liquid pumping pipe;

a liquid inlet of the second manual rocking type plunger pump is connected with the water injection tank through a second liquid pumping pipe, a third valve is arranged on the second liquid pumping pipe, a liquid injection port of the second manual rocking type plunger pump is respectively communicated with an upper pressurizing cavity above the upper pressure plate and a lower pressurizing cavity below the lower pressure plate through a second liquid injection pipe, and a third pressure gauge is arranged on the second liquid injection pipe;

the water pressure transmission pipe is provided with a fourth pressure gauge, a fourth valve and a digital display flowmeter, wherein the fourth pressure gauge is positioned between the fourth valve and the variable infiltration tank, and the fourth valve is positioned between the fourth pressure gauge and the digital display flowmeter.

The system is characterized by further comprising a data acquisition monitoring system, wherein the data acquisition monitoring system is a computer, and the data acquisition monitoring system is respectively connected with the first pressure gauge, the second pressure gauge, the third pressure gauge, the fourth pressure gauge and the digital display flow meter through data lines.

The variable permeability material is prepared by uniformly mixing dry coal powder and small rubber balls according to the weight ratio of 1: 6-1: 3, wherein the particle size of the dry coal powder is below 200 meshes, and the diameter of the small rubber balls is 1-3 mm.

A plurality of simulation mineshafts are sequentially arranged side by side and fixedly connected, and a handle and a pressure relief nut are arranged at the upper end part of the pressurizing cylinder.

By adopting the technical scheme, the specific process of the simulation test is as follows:

(1) preparing a variable-permeability material, determining the mixing ratio of the variable-permeability material according to the variable-permeability range, and filling the variable-permeability material into a variable-permeability cavity;

(2) the water pressure variable load system and the straight well drainage system are combined, installed and connected;

(3) checking the air tightness of the simulation test device;

(4) calibrating the variable permeability range of the permeability of the variable permeability material;

(5) setting the calibrated permeability to carry out a water pressure propagation distance simulation test;

(6) and analyzing and processing the data to finally obtain the water pressure propagation rule under different conditions.

The specific process of the step (1) is as follows: mixing and vibrating dry coal powder and small rubber balls uniformly according to the weight ratio of 1:3 to prepare a variable-permeability material for later use, unscrewing a fixing bolt, taking out a variable-permeability box, filling the mixed variable-permeability material into a variable-permeability cavity through a water pressure transmission pipe or an orifice connected with the variable-permeability box through a first liquid injection pipe, tamping the variable-permeability box by using a stick, reinstalling the variable-permeability box on a mounting seat, and screwing the fixing bolt; and sequentially charging other groups of hydraulic variable-load systems according to the process of charging the variable-permeability materials in one group of hydraulic variable-load systems.

The specific process of the step (3) is as follows: closing the second valve and the fourth valve, opening the first valve and starting the vacuum pump, vacuumizing the free volume inside the variable-permeability material filled in the variable-permeability cavity of the variable-permeability box for 30-60min until the reading on the vacuum pump is not more than 0.01MPa, and closing the vacuum pump and the first valve; then screwing in the plunger of the first hand-operated plunger pump to the innermost end position, opening the second valve, screwing out the plunger of the first hand-operated plunger pump to pump water from the water injection tank until the plunger of the first hand-operated plunger pump is screwed out to the outermost end position, and closing the second valve after the water pumping is finished; opening a fourth valve, screwing in a plunger of the first hand-operated plunger pump to inject water into the middle variation permeation cavity, closing the fourth valve when the digital display flowmeter starts to read, continuing screwing in the plunger of the first hand-operated plunger pump to inject water into the middle variation permeation cavity, and stopping screwing in the plunger of the first hand-operated plunger pump when the second pressure gauge and the fourth pressure gauge start to read and the difference between the readings of the second pressure gauge and the readings of the fourth pressure gauge is not more than 0.05MPa, namely completing water pressure loading; standing for 3-5h after the hydraulic pressure loading is finished, and judging that the air tightness of the device is good if no water dripping or water seepage condition exists at the pipe joint; if water drops or seeps at a certain pipe joint, the twine is used for winding at the certain pipe joint; and sequentially carrying out air tightness inspection on other groups of water pressure load-varying systems according to the process of carrying out air tightness inspection on one group of water pressure load-varying systems.

The specific process of the step (4) is as follows: because the permeability of each group of variable-permeability materials is different due to the difference of the spatial position and the distribution characteristics of the small particles of the variable-permeability materials in each group of hydraulic variable-load systems, the variation range of the adjustable permeability of each group of hydraulic variable-load systems needs to be calibrated after the airtightness inspection is finished; carrying out a charging process and an air tightness inspection process on each group of hydraulic variable-load devices, wherein all valves are in a closed state; opening a second valve, screwing out a plunger of the first hand-operated plunger pump to pump water pressure, stopping screwing out when the plunger of the first hand-operated plunger pump is screwed out to the outermost end of the pump body of the first hand-operated plunger pump, and closing the second valve; meanwhile, the second manual-rocking plunger pump is screwed out, the upper pressure plate resets under the action of the upper spring, the lower pressure plate resets under the action of the lower spring, after the operation is completed, the fourth valve is opened, the plunger of the first manual-rocking plunger pump is slowly screwed into the plunger at a constant speed to carry out water pressure loading, and at the moment, the data acquisition monitoring system carries out water pressure loading on the pressure of the second pressure gauge, the third pressure gauge and the fourth pressure gauge and the instantaneous flow of the digital display flowmeterQuantity q and cumulative flowQReading, wherein the reading of the third pressure gauge is 0, and when the instantaneous flow reading of the digital display flowmeter is basically stable, a formula is utilized

Initial permeability to a permeability-changing materialK ₁Calculating; in the formulaQIs the cumulative flow rate of water;Lthe length of the variable-permeability material is the distance from one side of the variable-permeability box connected with the first liquid injection pipe to one side connected with the hydraulic pressure transmission pipe; the method comprises the following steps of (1) knowing;Pthe pressure difference is the difference value of the second pressure gauge and the fourth pressure gauge;gis the acceleration of gravity;vthe water injection viscosity is adopted; meanwhile, slowly screwing in the plunger of the second hand-shaking plunger pump at a constant speed, and starting reading of a third pressure gauge at the momentP ₁And the readings of the second pressure gauge, the fourth pressure gauge and the digital display flowmeter begin to decline, namely any pressure point can be calculated according to a formulaP ₁The permeability of the lower opposite strain seepage material is increased, when the plunger of the second hand-operated plunger pump is screwed in continuously, water in the water injection tank is pressed into the upper pressurizing cavity and the lower pressurizing cavity, the upper pressure plate and the lower pressure plate move downwards and upwards respectively to pressurize the strain seepage material, when the permeability of the strain seepage material is not reduced obviously until a certain pressure point is reached, the first hand-operated plunger pump and the second hand-operated plunger pump are stopped to be loaded, and at the moment, the pressure point is increasedP ₁Permeability under correspondingK ₂Each pressure point can be obtainedP ₁The permeability curve under the corresponding condition, and the range of the permeability which can be controllably changed isK ₂-K ₁(ii) a At the moment, the controllable variable permeability range calibration process is finished; and then calibrating the variation range of the permeability of the variable permeability material in the other groups of hydraulic pressure variable load systems according to the process of calibrating the variation range of the permeability of the variable permeability material in one group of hydraulic pressure variable load systems.

The specific process of the step (5) is as follows: the pressurizing cylinder is fully upwards rotated to the uppermost end of the simulated shaft, then a fourth valve in each group of hydraulic variable-load system is opened, and the first manual-rocking plunger pump and the second manual-rocking plunger pump are operated simultaneouslyPressurizing by the plunger pumps, stopping operating the first manual rocking plunger pump and the second manual rocking plunger pump when the height of the water surface in the simulated shaft is 1/4-1/3 of the total length of the simulated shaft and the liquid level heights of the four groups of simulated shafts are the same, then opening the pressure relief nut and lowering the pressurizing cylinder to be in contact with the water surface in the simulated shaft, and closing the pressure relief nut; then operating the first manual plunger pump and the second manual plunger pump of each group of water pressure variable load system to pressurize properly, observing the pressure of the first pressure gauge, the second pressure gauge, the third pressure gauge and the fourth pressure gauge and reading of the digital display flowmeter at the moment, after the reading is stabilized for 0.5h, lifting the pressurizing cylinder in each simulation shaft upwards to the 1/2 position of the height of the simulation shaft, observing and recording the pressure of each first pressure gauge, the second pressure gauge, the third pressure gauge and the fourth pressure gauge and the reading of the digital display flowmeter, wherein the digital display flowmeter changes at the moment, and recording the time when the reading of the digital display flowmeter does not change after a certain timetThen a function of the instantaneous flow rate and time can be obtained

From the relational expression

Known flow rateVAnd timetIs a relational expression of

The formula is integrated, so that the propagation distance of the water pressure of the variable permeability material in the permeability state can be obtained. And (5) testing the transmission distance of the water pressure under other permeability according to the change range of the permeability-changing material marked in the step (4) and the operation process in the step (5).

The invention carries out pressure loading and unloading through more than two water pressure variable-load systems with permeability variable at any time, and simulates the change of permeability in the same horizontal direction due to the drainage and mining process; pressure is added and unloaded in the vertical direction through more than two groups of hand-operated plunger pumps, and the change of water pressure in the drainage stage of the coal-bed gas well vertical well is simulated; and calculating the water pressure attenuation coefficient under different permeability by using the flowmeter and a computer program so as to obtain the water pressure propagation distance. And monitoring the water pressure of each water pressure variable load system and the water pressure of the hand-operated plunger pump as the basis for calculating the water pressure propagation attenuation parameters.

In conclusion, the method can truly monitor the permeability change in different directions in the coal bed gas vertical well drainage and production process; the method can monitor the water pressure propagation rule caused by permeability change in different directions in the drainage and production process of the coal bed gas well more truly, and can test the water pressure propagation distance more accurately under the conditions of different reservoir permeability and permeability change in the drainage and production process, so as to lay a foundation for accurately predicting the gas production of the coal bed gas vertical well.

Drawings

FIG. 1 is a schematic overall layout of the present invention;

FIG. 2 is an enlarged schematic view of the hydraulic loading system of FIG. 1;

fig. 3 is a schematic elevation view of the vertical well drainage system of fig. 1.

Detailed Description

As shown in fig. 1-3, the device for simulating and testing the water pressure propagation distance in the coal bed methane vertical well drainage process of the invention comprises a vertical well drainage system 1 and a plurality of groups of water pressure variable load systems 2, wherein four groups of water pressure variable load systems 2 are arranged in the embodiment, and the water pressure variable load systems 2 are arranged around the vertical well drainage system 1; the vertical well drainage system 1 comprises a base 3 and a support 4, wherein simulation shafts 5 with the number equal to that of the water pressure variable load system 2 are arranged on the base 3 along the vertical direction, the lower end of the support 4 is fixedly arranged on one side of the base 3, a pressurizing cylinder 6 is hermetically connected in each simulation shaft 5 in a threaded manner, the upper end of the pressurizing cylinder 6 is blocked, the lower end of the pressurizing cylinder 6 is open and communicated with the inside of the simulation shaft 5, guide holes 7 which are in one-to-one correspondence with the upper part and the lower part of the simulation shaft 5 are arranged at the top of the support 4, the pressurizing cylinder 6 is arranged in the guide holes 7 in a penetrating manner, the simulation shaft 5 and the pressurizing cylinder 6 are both made of transparent materials, the side part of the simulation shaft 5 is provided with scales 8 along the axial direction, and the lower part of each simulation shaft 5 is connected with a first pressure gauge 9; each group of hydraulic variable load systems 2 is correspondingly connected with the lower port of the simulation shaft 5 through a hydraulic transmission pipe 10 penetrating through the base 3.

Each group of hydraulic variable load systems 2 comprises a first manual rocking plunger pump 11, a second manual rocking plunger pump 12, a vacuum pump 13, a water injection tank 14 and a controllable variable seepage device;

the controllable variable infiltration device comprises a mounting seat 15, a variable infiltration box 16 in a cuboid shape is fixedly arranged on the mounting seat 15 through a fixing bolt, an upper pressure plate 17 and a lower pressure plate 18 are horizontally arranged in the variable infiltration box 16, the inner parts of the variable infiltration box 16 of the upper pressure plate 17 and the lower pressure plate 18 are divided into an upper pressurizing cavity 19 from top to bottom, the variable infiltration chamber comprises an upper pressing plate 17 and a lower pressing chamber 21, the peripheral outer walls of the upper pressing plate 17 and the lower pressing plate 18 are connected with the periphery of the inner wall of a variable infiltration box 16 in a sliding and sealing mode, a variable infiltration material 22 is filled in a variable infiltration chamber 20 formed between the upper pressing plate 17 and the lower pressing plate 18 in the variable infiltration box 16, an upper spring 23 is arranged between the upper side surface of the upper pressing plate 17 and the top of the variable infiltration box 16, a lower spring 24 is arranged between the lower side surface of the lower pressing plate 18 and the bottom of the variable infiltration box 16, a liquid injection port of a first hand-cranking plunger pump 11 is communicated with the outer side of the variable infiltration chamber 20 through a first liquid injection pipe 42, and the inner side of the variable infiltration chamber 20 is communicated with one end of the hydraulic transmission pipe 10;

the vacuum pump 13 is respectively connected with the first liquid injection pipe 42 and the hydraulic pressure transmission pipe 10 through a first vacuumizing pipe 25 and a second vacuumizing pipe 26, and the first vacuumizing pipe 25 and the second vacuumizing pipe 26 are both provided with a first valve 27;

the first hand-operated plunger pump 11 is provided with a second pressure gauge 28, a liquid inlet of the first hand-operated plunger pump 11 is connected with the water injection tank 14 through a first liquid pumping pipe 29, and the first liquid pumping pipe 29 is provided with a second valve 30;

a liquid inlet of the second manual-rocking plunger pump 12 is connected with the water injection tank 14 through a second liquid pumping pipe 31, a third valve 32 is arranged on the second liquid pumping pipe 31, a liquid injection port of the second manual-rocking plunger pump 12 is respectively communicated with an upper pressurizing cavity 19 above the upper pressure plate 17 and a lower pressurizing cavity 21 below the lower pressure plate 18 through a second liquid injection pipe 33, and a third pressure gauge 34 is arranged on the second liquid injection pipe 33;

the water pressure transmission pipe 10 is provided with a fourth pressure gauge 35, a fourth valve 36 and a digital display flowmeter 37, wherein the fourth pressure gauge 35 is positioned between the fourth valve 36 and the variable infiltration tank 16, and the fourth valve 36 is positioned between the fourth pressure gauge 35 and the digital display flowmeter 37.

The invention also comprises a data acquisition monitoring system 38, the data acquisition monitoring system 38 is a computer, and the data acquisition monitoring system 38 is respectively connected with the first pressure gauge 9, the second pressure gauge 28, the third pressure gauge 34, the fourth pressure gauge 35 and the digital display flow meter 37 through data lines 41.

The variable permeability material 22 is formed by uniformly mixing dry coal powder and small rubber balls according to the weight ratio of 1: 6-1: 3, wherein the particle size of the dry coal powder is less than 200 meshes, and the diameter of the small rubber balls is 1mm-3 mm.

A plurality of simulated shafts 5 are sequentially arranged side by side and fixedly connected, and the upper end part of the pressurizing cylinder 6 is provided with a handle 39 and a pressure relief nut 40.

The specific process of the simulation test of the invention is as follows:

(1) preparing a variable-permeability material 22, determining the mixing ratio of the variable-permeability material 22 according to the variable-permeability range, and filling the variable-permeability material 22 into a variable-permeability cavity 20;

(2) the water pressure variable load system 2 and the vertical well drainage system 1 are assembled and connected;

(3) checking the air tightness of the simulation test device;

(4) calibrating the variable permeability range of the permeability of the variable permeability material 22;

(5) setting the calibrated permeability to carry out a water pressure propagation distance simulation test;

(6) and analyzing and processing the data to finally obtain the water pressure propagation rule under different conditions.

The specific process of the step (1) is as follows: mixing and vibrating dry coal powder and small rubber balls uniformly according to the weight ratio of 1:3 to prepare a variable-permeability material 22 for later use, unscrewing a fixing bolt, taking out the variable-permeability box 16, filling the mixed variable-permeability material 22 into a variable-permeability cavity through an orifice connected with the variable-permeability box 16 through a water pressure transmission pipe 10 or a first liquid injection pipe 42, compacting by using a rod, reinstalling the variable-permeability box 16 onto a mounting seat 15, and screwing the fixing bolt; the other sets of hydraulic pressure loading systems 2 are sequentially loaded according to the process of loading the variable permeability materials 22 in one set of hydraulic pressure loading systems 2.

The specific process of the step (3) is as follows: closing the second valve 30 and the fourth valve 36, opening the first valve 27 and starting the vacuum pump 13, vacuumizing the free volume inside the variable-permeability material 22 filled in the variable-permeability cavity 20 of the variable-permeability box 16 for 30-60min until the reading on the vacuum pump 13 is not more than 0.01MPa, and closing the vacuum pump 13 and the first valve 27; then screwing in the plunger of the first hand-operated plunger pump 11 to the innermost end position, opening the second valve 30, screwing out the plunger of the first hand-operated plunger pump 11 to pump water from the water injection tank 14 until the plunger of the first hand-operated plunger pump 11 is screwed out to the outermost end position, and closing the second valve 30 when water pumping is finished; opening a fourth valve 36, screwing in a plunger of the first hand-operated plunger pump 11 to fill water into the middle variable-permeability cavity 20, closing the fourth valve 36 when the digital display flowmeter 37 starts to read, continuing screwing in the plunger of the first hand-operated plunger pump 11 to fill water into the middle variable-permeability cavity, and stopping screwing in the plunger of the first hand-operated plunger pump 11 when the second pressure gauge 28 and the fourth pressure gauge 35 start to read and the difference between the readings of the second pressure gauge and the fourth pressure gauge is not more than 0.05MPa, namely completing water pressure loading; standing for 3-5h after the hydraulic pressure loading is finished, and judging that the air tightness of the device is good if no water dripping or water seepage condition exists at the pipe joint; if water drops or seeps at a certain pipe joint, the twine is used for winding at the certain pipe joint; and sequentially carrying out air tightness inspection on other groups of hydraulic pressure load-varying systems 2 according to the air tightness inspection process of one group of hydraulic pressure load-varying systems 2.

The specific process of the step (4) is as follows: because the permeability of each group of variable permeability materials 22 is different due to the difference of the spatial position and the distribution characteristics of the small particles of the variable permeability materials 22 in each group of hydraulic variable load systems 2, the variation range of the adjustable permeability of each group of hydraulic variable load systems 2 needs to be calibrated after the airtightness inspection is finished; carrying out a charging process and an air tightness inspection process on each group of hydraulic variable-load devices, wherein all valves are in a closed state; firstly opening the second valve 30, screwing out the plunger of the first hand-operated plunger pump 11 to pump water pressure, stopping screwing out when the plunger of the first hand-operated plunger pump 11 is screwed out to the outermost end of the pump body of the first hand-operated plunger pump 11, and closing the second valve 30; at the same time, the second hand is rotated outIn the plunger pump 12, the upper pressure plate 17 is reset under the action of the upper spring 23, the lower pressure plate 18 is reset under the action of the lower spring 24, after the operation is completed, the fourth valve 36 is opened, the plunger of the first manual plunger pump 11 is slowly screwed into the plunger at a constant speed to carry out water pressure loading, and at the moment, the data acquisition monitoring system 38 carries out water pressure loading on the pressure of the second pressure gauge 28, the third pressure gauge 34 and the fourth pressure gauge 35 and the instantaneous flow q and the accumulated flow q of the digital display flowmeter 37QReading, wherein the reading of the third pressure gauge 34 is 0, and when the instantaneous flow reading of the digital display flow meter 37 is basically stable, the formula is utilized

Initial permeability to the varied permeability material 22K ₁Calculating; in the formulaQIs the cumulative flow rate of water;Lthe length of the variable-permeability material 22 is the distance from the variable-permeability box 16 on the side connected with the first liquid injection pipe 42 to the side connected with the hydraulic pressure transmission pipe 10; the method comprises the following steps of (1) knowing;Pis the pressure difference, i.e. the difference between the second pressure gauge 28 and the fourth pressure gauge 35; g is the acceleration of gravity;vthe water injection viscosity is adopted; at the same time, the plunger of the second hand-operated plunger pump 12 is slowly screwed in at a constant speed, and the third pressure gauge 34 begins to read at the momentP ₁And the readings of the second pressure gauge 28, the fourth pressure gauge 35 and the digital display flow meter 37 begin to decrease, i.e. any pressure point can be calculated according to the formulaP ₁When the plunger of the second manual-rocking plunger pump 12 is screwed in continuously, water in the water injection tank 14 is pressed into the upper pressurizing cavity 19 and the lower pressurizing cavity 21, the upper pressure plate 17 and the lower pressure plate 18 move downwards and upwards respectively to pressurize the variable-permeation material 22 until the permeability of the variable-permeation material 22 does not drop obviously after the materials are pressurized to a certain pressure point, the first manual-rocking plunger pump 11 and the second manual-rocking plunger pump 12 are stopped to be loaded, and the pressure point is at the momentP ₁Permeability under correspondingK ₂Each pressure point can be obtainedP ₁The permeability curve under the corresponding condition, and the range of the permeability which can be controllably changed isK ₂-K ₁(ii) a At the moment, the controllable variable permeability range calibration process is finished; then one group is matched according to the aboveThe process of calibrating the variation range of the permeability of the variable permeability material 22 in the hydraulic loading system 2 calibrates the variation range of the permeability of the variable permeability material 22 in the other sets of hydraulic loading systems 2.

The specific process of the step (5) is as follows: fully screwing the pressure increasing cylinder 6 to the uppermost end of the simulated shaft 5, then opening a fourth valve 36 in each group of hydraulic pressure variable load system 2, simultaneously operating the first hand-operated plunger pump 11 and the second hand-operated plunger pump 12 to increase the pressure, stopping operating the first hand-operated plunger pump 11 and the second hand-operated plunger pump 12 when the height of the water surface in the simulated shaft 5 is between 1/4 and 1/3 of the total length of the simulated shaft 5 and the heights of the water surfaces in the four groups of simulated shafts 5 are the same, then opening the pressure relief nut 40 and lowering the pressure increasing cylinder 6 to be in contact with the water surface in the simulated shaft 5, and closing the pressure relief nut 40; at the moment, the first manual-rocking plunger pump 11 and the second manual-rocking plunger pump 12 of each group of water pressure variable load system 2 are operated to pressurize properly, the pressure of the first pressure gauge 9, the second pressure gauge 28, the third pressure gauge 34 and the fourth pressure gauge 35 and the reading of the digital display flow meter 37 are observed, after the reading is stabilized for 0.5 hour, the pressure cylinder 6 in each simulated shaft 5 is lifted upwards to the 1/2 position of the height of the simulated shaft 5, the pressure of each first pressure gauge 9, the second pressure gauge 28, the third pressure gauge 34 and the fourth pressure gauge 35 and the reading of the digital display flow meter 37 are observed and recorded, at the moment, the digital display flow meter 37 changes, and when the reading of the digital display flow meter 37 does not change any more after a certain time, the reading of the digital display flow meter 37 is recorded for the timetThen a function of the instantaneous flow rate and time can be obtained

From the relational expression

Known flow rateVAnd timetIs a relational expression of

The formula is integrated to obtain the propagation distance of the water pressure of the variable permeability material 22 in this permeability state. According to the infiltration-changed material 2 marked in the step (4)2, testing the transmission distance of the water pressure under other permeability according to the operation process in the step (5).

The invention carries out pressure loading and unloading through more than two water pressure variable load systems 2 with permeability variable at any time, and simulates the change of permeability in the same horizontal direction due to the drainage and mining process; pressure is added and unloaded in the vertical direction through more than two groups of hand-operated plunger pumps, and the change of water pressure in the drainage stage of the coal-bed gas well vertical well is simulated; and calculating the water pressure attenuation coefficient under different permeability by using the flowmeter and a computer program so as to obtain the water pressure propagation distance. And monitoring the water pressure of each water pressure variable load system 2 and the water pressure of the hand-operated plunger pump as the basis for calculating the water pressure propagation attenuation parameters.

The present embodiment is not intended to limit the shape, material, structure, etc. of the present invention in any way, and any simple modification, equivalent change and modification made to the above embodiments according to the technical spirit of the present invention are within the scope of the technical solution of the present invention.

Claims (4)

1. Coal bed gas vertical shaft drainage process water pressure propagation distance simulation test device, its characterized in that: the system comprises a vertical well drainage system and a plurality of groups of water pressure variable load systems, wherein the water pressure variable load systems are arranged around the vertical well drainage system; the vertical well drainage system comprises a base and a support, wherein simulation shafts equal to the hydraulic pressure variable load system in number are arranged on the base in the vertical direction, the lower end of the support is fixedly arranged on one side of the base, a pressurizing cylinder is connected in each simulation shaft in a threaded sealing manner, the upper end of the pressurizing cylinder is blocked, the lower end of the pressurizing cylinder is opened and communicated with the inside of the simulation shaft, guide holes corresponding to the simulation shafts one by one are formed in the top of the support, the pressurizing cylinders are arranged in the guide holes in a penetrating manner, the simulation shafts and the pressurizing cylinders are made of transparent materials, scales are arranged on the side parts of the simulation shafts in the axial direction, and the lower part of each simulation shaft is connected with a first pressure gauge; each group of water pressure variable load systems are correspondingly connected with the lower port of the simulation shaft through a water pressure transmission pipe penetrating through the inside of the base;

each group of water pressure variable-load systems comprises a first manual rocking plunger pump, a second manual rocking plunger pump, a vacuum pump, a water injection tank and a controllable variable-seepage device;

the controllable variable-permeability device comprises a mounting seat, a variable-permeability box in a cuboid shape is fixedly arranged on the mounting seat through a fixing bolt, an upper pressing plate and a lower pressing plate are horizontally arranged in the variable-permeability box, the inner parts of the variable-permeability box are divided into an upper pressurizing cavity, a middle-variable-permeability cavity and a lower pressurizing cavity from top to bottom, the peripheral outer walls of the upper pressing plate and the lower pressing plate are in sliding sealing connection with the periphery of the inner wall of the variable-permeability box, a variable-permeability material is filled in the middle-variable-permeability cavity formed between the upper pressing plate and the lower pressing plate in the variable-permeability box, an upper spring is arranged between the upper side surface of the upper pressing plate and the top of the variable-permeability box, a lower spring is arranged between the lower side surface of the lower pressing plate and the bottom of the variable-permeability box, a liquid injection port of the first hand-operated plunger pump is communicated with the outer side of the middle-variable-permeability cavity through a first liquid injection pipe, and the inner side of the middle-variable-permeability cavity is communicated through one end of a hydraulic transmission pipe;

the vacuum pump is respectively connected with the first liquid injection pipe and the water pressure transmission pipe through a first vacuum pipe and a second vacuum pipe, and the first vacuum pipe and the second vacuum pipe are respectively provided with a first valve;

a second pressure gauge is arranged on the first hand-cranking plunger pump, a liquid inlet of the first hand-cranking plunger pump is connected with the water injection tank through a first liquid pumping pipe, and a second valve is arranged on the first liquid pumping pipe;

a liquid inlet of the second manual rocking type plunger pump is connected with the water injection tank through a second liquid pumping pipe, a third valve is arranged on the second liquid pumping pipe, a liquid injection port of the second manual rocking type plunger pump is respectively communicated with an upper pressurizing cavity above the upper pressure plate and a lower pressurizing cavity below the lower pressure plate through a second liquid injection pipe, and a third pressure gauge is arranged on the second liquid injection pipe;

the water pressure transmission pipe is provided with a fourth pressure gauge, a fourth valve and a digital display flowmeter, wherein the fourth pressure gauge is positioned between the fourth valve and the variable infiltration tank, and the fourth valve is positioned between the fourth pressure gauge and the digital display flowmeter.

2. The device for simulating and testing the water pressure propagation distance in the drainage and production process of the coal bed gas vertical well according to claim 1, is characterized in that: the system is characterized by further comprising a data acquisition monitoring system, wherein the data acquisition monitoring system is a computer, and the data acquisition monitoring system is respectively connected with the first pressure gauge, the second pressure gauge, the third pressure gauge, the fourth pressure gauge and the digital display flow meter through data lines.

3. The device for simulating and testing the water pressure propagation distance in the drainage and production process of the coal bed gas vertical well according to claim 1, is characterized in that: the variable permeability material is prepared by uniformly mixing dry coal powder and small rubber balls according to the weight ratio of 1: 6-1: 3, wherein the particle size of the dry coal powder is below 200 meshes, and the diameter of the small rubber balls is 1-3 mm.

4. The device for simulating and testing the water pressure propagation distance in the drainage and production process of the coal bed gas vertical well according to claim 1, is characterized in that: a plurality of simulation mineshafts are sequentially arranged side by side and fixedly connected, and a handle and a pressure relief nut are arranged at the upper end part of the pressurizing cylinder.

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