CN212275523U - Thick oil well sand control effect evaluation testing arrangement - Google Patents

Abstract

The utility model relates to a viscous crude sand control effect evaluation testing arrangement, including the test section of thick bamboo of vertical setting, the upper end of test section of thick bamboo is connected with can be to the air supply of the cavity of test section of thick bamboo conveying gas in, and the bottom level of neighbouring cavity is equipped with the backup pad that has a plurality of through-holes, leaves certain clearance between the bottom surface of backup pad and cavity, is equipped with the screen pipe in the backup pad top and filters the appearance piece, and the top that just is located the screen pipe in the cavity and filters the appearance piece is filled there is the simulation mortar of misce bene. The lower end face of the test cylinder is provided with a liquid outlet communicated with the space formed by the gaps, a liquid discharge valve is arranged at the liquid outlet, and a measuring cylinder is arranged below the test cylinder and corresponding to the liquid outlet. The utility model discloses the cost of manufacture is low, and experimental period is short, can simulate the process that the sand grain formed the sand bridge on the screen pipe surface, and the sand control principle is closer with actual conditions, and the test result is more accurate.

Description

Thick oil well sand control effect evaluation testing arrangement

Technical Field

The utility model relates to an oil gas well exploitation technical field especially relates to a viscous crude well sand control effect evaluation testing arrangement.

Background

The problem of formation sand production is commonly existed in the process of exploitation of a thick oil well due to stratum looseness and high crude oil viscosity. In order to ensure the normal exploitation of the sand producing well, a matched sand control measure is required. The screen sand control technology (i.e. the screen sand control technology is only used) and the gravel packing sand control technology (i.e. the dual sand control technology using the screen and the gravel layer) are two sand control technologies which are most widely applied at present. The optimal design of the sand control process is carried out by selecting proper sizes of the sand control screen pipe and the gravel, which is the premise of ensuring the sand control effect.

Currently, selection of sand control screens and design of gravel size are mainly determined by means of empirical formula calculation and field experience, and the method has great limitations and inaccuracy. In order to more scientifically guide the design of the sand control process of the sieve tube, researchers develop various evaluation test devices and evaluation test methods for evaluating the sand control effect of the sieve tube. The existing sand control effect evaluation testing device mainly has two types: a full-size screen pipe model and a sand control sample piece model. The two models are both characterized in that simulated sand is filled outside the sieve tube or the sand control sample piece, then simulated liquid is injected, and the sand control effect of the sieve tube is evaluated by testing the sand production amount and the pressure difference change.

The full-size sieve tube model is matched with an autoclave, a high-pressure pump, a liquid preparation tank, a data acquisition system and the like, and is mainly used for simulating the production and sand prevention conditions of an oil well as simulating the underground conditions, preparing simulation liquid and conveying the simulation liquid by utilizing the devices as much as possible. The sand control sample piece model requires a precise infusion pump and a data acquisition system, and the manufacturing cost of the test device is relatively high. Moreover, in actual work, the design of the sand control scheme is often required to be completed within 2-3 days, the existing sand control test device is adopted for sieve tube selection and gravel size design, a longer test period is needed, and the design requirement is difficult to meet.

In addition, both models were run after filling with dry-mixed simulated sand. The simulated sand is experimental sand prepared by adopting sand grains with different grain sizes according to the grain size distribution of the formation sand, and the condition of uneven sand mixing is easy to occur when the preparation method is used for dry mixing, so that the experimental result has larger deviation. In the experimental process, the problem of poor reproducibility of experimental results caused by uneven sand mulling often occurs. Moreover, because production conditions of an oil well need to be simulated, equipment such as a high-pressure pump needs to be utilized, at present, only simulated sand can be filled in advance, and then liquid is injected for an experiment, and the process of forming a sand bridge when formation sand contacts a sieve tube or a gravel layer cannot be reflected, so that certain deviation exists between the experimental result and the actual situation.

Therefore, the inventor provides a thick oil well sand control effect evaluation testing device by means of experience and practice of related industries for many years so as to overcome the defects of the prior art.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a viscous crude well sand control effect evaluation testing arrangement, the cost of manufacture is low, and experimental period is short, can simulate the process that the sand grain formed the sand bridge on the screen pipe surface, and the sand control principle is closer with actual conditions, and the test result is more accurate.

The utility model aims at realizing the method, and provides a thick oil well sand control effect evaluation testing device, which comprises a vertically arranged testing cylinder with a cavity; the upper end of the test cylinder is connected with an air source capable of conveying air into a cavity of the test cylinder, a support plate with a plurality of through holes is horizontally arranged at the bottom close to the cavity, a certain gap is reserved between the support plate and the bottom surface of the cavity, a sieve tube filtering sample piece is arranged above the support plate, and simulation mortar which is uniformly mixed is filled in the cavity and is positioned above the sieve tube filtering sample piece; the lower end face of the test cylinder is provided with a liquid outlet communicated with the space formed by the gaps, a liquid discharge valve is arranged at the liquid outlet, and a measuring cylinder is arranged below the test cylinder and corresponding to the liquid outlet.

In a preferred embodiment of the present invention, a gravel layer is further filled above the screen filtering sample.

In a preferred embodiment of the present invention, the inner wall of the lower end of the testing cylinder is located below the supporting plate to form a taper hole with a diameter gradually reduced downwards and communicated with the liquid outlet.

In a preferred embodiment of the present invention, the cross-sectional area of the liquid outlet is larger than the flow area of the sieve tube filtering sample.

In a preferred embodiment of the present invention, a diameter-reduced limit ring is formed on the inner wall of the test cartridge and above the screen filter sample.

The utility model discloses an among the preferred embodiment, press from both sides and establish a sealing washer between spacing bulge loop and screen pipe filtration appearance piece, the up end top of sealing washer leans on the lower terminal surface of spacing bulge loop, and the lower terminal surface of sealing washer supports and leans on the up end edge that the screen pipe filtered appearance piece.

In a preferred embodiment of the present invention, the drain valve is a butterfly valve.

The utility model discloses an among the preferred embodiment, the air supply includes the gas bomb, and the gas bomb passes through the pipeline to be connected with the upper end of a test section of thick bamboo to be equipped with the air-vent valve on the pipeline, be connected with the manometer in the upper end of a test section of thick bamboo.

In a preferred embodiment of the present invention, the testing cylinder includes a containing cylinder with openings at two ends, an upper cover and a lower cover; an upper pipe body vertically penetrating through the upper cover is arranged in the upper cover, the upper pipe body is communicated with the cavity, the upper cover can be detachably and hermetically connected with the upper end of the containing cylinder, the pressure gauge is connected with the upper end of the upper pipe body, and the side wall of the upper end of the upper pipe body is provided with an air inlet and is connected with a pipeline; the lower cover can be dismantled sealing connection with the lower extreme that holds a section of thick bamboo, and the inner wall of lower cover constitutes foretell taper hole, and body, foretell flowing back valve are established on the body down to the liquid outlet down.

In a preferred embodiment of the utility model, the utility model further comprises a support frame, the support frame comprises a bottom plate, two vertical support rods fixed on the bottom plate and two horizontal support rods fixed between the two vertical support rods, the two vertical support rods are arranged in parallel at intervals, the two horizontal support rods are arranged in parallel at intervals, and the two horizontal support rods are respectively provided with an upper mounting hole and a lower mounting hole which are coaxially arranged from top to bottom; the test cylinder is arranged between the two transverse support rods, the upper pipe body penetrates through the upper mounting hole and extends upwards, the lower pipe body penetrates through the lower mounting hole and extends downwards, and the measuring cylinder is placed on the bottom plate.

From the above, the utility model provides an evaluation testing arrangement packs the simulation mortar of misce bene in the cavity, just mixes simulation sand and simulation liquid misce bene promptly before the test, this compares with the mode that adopts among the prior art to mix simulation sand filling and then pour into the simulation liquid and carry out the experiment, can guarantee on the one hand that the sand grain of each particle size in the simulation sand fully mixes, reduces the experiment deviation; on the other hand, because the sand control process of actual viscous crude well is the process that the grit in the crude oil fell on the screen pipe and constantly piles up from the stratum bit by bit, the utility model discloses to fall the simulation mortar on the screen pipe filters the appearance spare, simulation sand suspension is in liquid, utilizes the air supply to carry gas in to the cavity, and the sand grain will be a bit down under gaseous effect, and the sand grain that is blockked down by the screen pipe filters the appearance spare and pile up gradually at the screen pipe and form the sand bridge, and then that blocks can't live falls into the graduated flask, and this sand control process is closer with actual conditions more, can simulate the process that the sand grain formed the sand bridge at the screen pipe, and the test result is.

The whole device does not need to completely simulate the actual production conditions of an oil well, but tests the sand control effect by simulating the movement process of sand flowing to the sieve tube, thus, the sand control effect can be reflected by only measuring the flowing speed and the sand output amount when the sand flows to the sieve tube, the whole device has a simple structure, the high-pressure kettle body and the high-performance infusion pump are not needed, the manufacturing cost is low, the experimental operation is simple, the experimental period is short, the experimental efficiency is high, and the sand control effect evaluation experiment of various sieve tube parameters under the conditions of the same formation sand and the same crude oil viscosity can be quickly completed.

Drawings

The drawings are only intended to illustrate and explain the present invention and do not limit the scope of the invention. Wherein:

FIG. 1: do the utility model provides a viscous crude sand control effect evaluation testing arrangement's schematic structure diagram.

FIG. 2: which is a partial enlargement at a in fig. 1.

FIG. 3: do the utility model provides a structural schematic of backup pad.

The reference numbers illustrate:

1. a support frame;

2. a test cartridge; 21. an upper cover; 211. a pipe body is arranged; 22. a receiving cylinder; 221. a limit convex ring; 23. a lower cover; 231. a lower pipe body; 2311. a drain valve;

3. a support plate; 4. the sieve tube filters the sample piece; 5. a seal ring;

6. a pressure gauge; 7. a pressure regulating valve; 8. a gas source; 9. a measuring cylinder.

Detailed Description

In order to clearly understand the technical features, objects, and effects of the present invention, embodiments of the present invention will be described with reference to the accompanying drawings.

As shown in fig. 1, fig. 2 and fig. 3, this embodiment provides a thick oil well sand control effect evaluation testing arrangement, including vertical setting and the test tube 2 that has the cavity, the upper end of test tube 2 is connected with can be to the gaseous air supply 8 of test tube 2's cavity internal transfer, the bottom level of neighbouring cavity is equipped with the backup pad 3 that has a plurality of through-holes, leave certain clearance between the bottom surface of backup pad 3 and cavity, it filters appearance spare 4 to be equipped with the screen pipe above backup pad 3, it has the simulation mortar of misce bene to fill in the cavity and the top that is located the screen pipe and filters appearance spare 4. The lower end face of the testing cylinder 2 is provided with a liquid outlet communicated with the space formed by the gap, a liquid discharge valve 2311 is arranged at the liquid outlet, and a measuring cylinder 9 is arranged below the testing cylinder 2 and corresponding to the liquid outlet.

The gas to be supplied into the chamber may be selected as desired, for example, nitrogen. Before testing, taking a stratum sand sample in the heavy oil well, and testing and analyzing the stratum sand sample; then mixing quartz sand with different grain diameters to prepare simulated sand with similar characteristics of the medium grain size, the separation coefficient, the mud content and the like of the stratum sand sample, and uniformly mixing; preparing a simulation liquid with the viscosity similar to that of crude oil in a heavy oil well by adopting a high-molecular tackifier and clear water; and then, uniformly mixing the simulated sand and the simulated liquid to obtain simulated mortar with a certain concentration, and adopting the same mortar concentration when performing the same group of comparison experiments.

When testing is carried out, the drain valve 2311 is closed, and the simulation mortar is poured into the cavity of the testing cylinder 2; then, gas with certain pressure is conveyed into the chamber through a gas source 8, and the conveyed gas adopts the same pressure value when the same group comparison experiment is carried out; then, opening a drain valve 2311, simultaneously and quickly pressing a timer, under the displacement action of gas pressure, enabling simulation liquid to filter the sample piece 4 through the sieve tube, gradually accumulating simulation sand on the surface of the sieve tube filter sample piece 4 to form a sand bridge, observing and evaluating the liquid outlet condition of the testing device in the process, closing the timer when the liquid outlet stops discharging liquid, and recording the time t of the timer; then recording the amount of the simulated mortar in the measuring cylinder 9, and analyzing the amount to obtain the sand content ratio eta of the simulated mortar in the measuring cylinder 9; this time, the experiment was completed. Then, the screen pipe filtering sample piece 4 with different types and/or sand blocking precision is replaced, the previous steps are repeated, and other experiments are carried out.

After the same group of comparison experiments are completed, the sand control effect of the sand control screen pipe under the corresponding stratum sand condition is evaluated by adopting two parameters, namely the sand content ratio eta and the timer time t of the simulated mortar in the measuring cylinder 9, and the smaller the sand content ratio eta and the timer time t are, the better the sand control effect is shown to be, so that the screen pipe type and the sand control precision with the best sand control effect under the stratum sand condition are selected.

Therefore, the evaluation testing device in the embodiment fills the simulation mortar which is uniformly mixed in the cavity, namely the simulation sand and the simulation liquid are uniformly mixed before testing, compared with the mode that the simulation liquid is injected after the simulation sand is filled in a dry mixing manner to carry out an experiment in the prior art, on one hand, the sand grains with various grain sizes in the simulation sand can be fully mixed, and the experiment deviation is reduced; on the other hand, because the sand control process of the actual heavy oil well is a process that sand in crude oil falls on the sieve tube from the stratum little by little and is continuously accumulated, in the embodiment, the simulated mortar is poured on the sieve tube filtering sample piece 4, the simulated sand is suspended in liquid, the air source 8 is utilized to convey air into the chamber, sand grains sink down little by little under the action of the air, the sand grains blocked by the sieve tube filtering sample piece 4 are gradually accumulated on the sieve tube filtering sample piece 4 to form a sand bridge, and the sand grains which cannot be blocked fall into the measuring cylinder 9, the sand control process is closer to the actual situation, the process that the sand grains form the sand bridge on the sieve tube can be simulated, and the test result is more accurate.

The whole device does not need to completely simulate the actual production conditions of an oil well, but tests the sand control effect by simulating the movement process of sand flowing to the sieve tube, thus, the sand control effect can be reflected only by measuring the flowing speed of the sand flowing to the sieve tube and the sand output (namely the time t of the timer and the sand content eta) of the sand flowing to the sieve tube, the whole device has simple structure, does not need a high-pressure kettle body and a high-performance infusion pump, has low manufacturing cost, simple experiment operation, short experiment period and high experiment efficiency, and can quickly finish the sand control effect evaluation experiment of various sieve tube parameters under the conditions of the same formation sand and the same crude oil viscosity.

It should be noted that when the gravel packing sand control effect test is required, a gravel layer is further filled above the screen filter sample 4. After each experiment, the gravel layer with different sizes or the screen filtering sample piece 4 with different types and/or precisions can be replaced simultaneously. In this way, the process of sand bridge formation on the surface of the gravel layer by sand grains can be simulated, and the sand control effect of the gravel layer can be tested.

In a specific implementation manner, in order to further improve the accuracy of the test, as shown in fig. 1, a taper hole with a diameter gradually reduced downwards and communicated with the liquid outlet is formed on the inner wall of the lower end of the test cylinder 2 and below the support plate 3. The lower end face of the supporting plate 3 abuts against the top face of the taper hole, so that the taper hole forms a funnel structure, fluid can pass through the funnel structure more conveniently, and the phenomenon that sand grains are accumulated on two sides of the bottom of the space formed by the gap and cannot fall into the measuring cylinder 9, and the amount of simulated mortar in the measuring cylinder 9 is deviated is avoided.

Further, the cross-sectional area of the liquid outlet is larger than the flow area of the screen filtering sample piece 4.

The overflowing area of the sieve tube filtering sample piece 4 refers to the sum of the areas of the filtering holes in the sieve tube filtering sample piece 4, so that the flowing speed of the simulated mortar flowing out of the sieve tube filtering sample piece 4 is not influenced by the liquid outlet, the time deviation of the timer caused by the throttling effect generated when the fluid passes through the liquid outlet is prevented, and the testing accuracy is further improved.

In practical application, in order to limit the screen filter sample 4, a limit convex ring 221 with a reduced diameter is formed on the inner wall of the test cartridge 2 and above the screen filter sample 4.

In order to prevent sand from passing through the edge of the screen filtering sample 4 to influence the testing accuracy, a sealing ring 5 is clamped between the limiting convex ring 221 and the screen filtering sample 4, the upper end face of the sealing ring 5 abuts against the lower end face of the limiting convex ring 221, and the lower end face of the sealing ring 5 abuts against the edge of the upper end face of the screen filtering sample 4.

Specifically, the inner diameter of the seal ring 5 is the same as the inner diameter of the limit convex ring 221, the seal ring 5 is made of soft rubber, the surface of the sieve tube filtering sample 4 is uneven due to a plurality of filtering holes, and the seal ring 5 can be squeezed into the holes (namely the filtering holes) of the sieve tube filtering sample 4 when the seal ring 5 is placed, so as to ensure the sealing effect on the edge of the sieve tube filtering sample 4.

In order to reduce the opening and closing time of the drain valve 2311 as much as possible and improve the accuracy of the timer time, the drain valve 2311 is a butterfly valve, and the valve can be opened completely only by screwing a quarter of a circle, so that the operation is quicker.

Of course, other types of fast opening and closing valves may be used for the drain valve 2311 as needed, and this embodiment is merely exemplary.

Further, in order to facilitate adjustment and observation of the pressure of the gas delivered into the chamber, the gas source 8 includes a gas bomb connected to the upper end of the test cylinder 2 through a pipeline, a pressure regulating valve 7 is provided on the pipeline, and a pressure gauge 6 is connected to the upper end of the test cylinder 2.

In the implementation process, in order to facilitate installation, adding simulation mortar and replacing the screen filter sample 4, as shown in fig. 1, the test cartridge 2 includes a containing cartridge 22 with two open ends, an upper cover 21 and a lower cover 23. Be equipped with the vertical upper tube body 211 that runs through upper cover 21 in the upper cover 21, upper tube body 211 and cavity intercommunication, sealing connection can be dismantled with the upper end that holds a section of thick bamboo 22 to upper cover 21, and foretell manometer 6 is connected with the upper end of upper tube body 211, and the inlet port has been seted up to the upper end lateral wall of upper tube body 211 and has been connected with foretell tube coupling. The lower cap 23 is detachably and hermetically connected to the lower end of the container 22, the inner wall of the lower cap 23 forms the tapered hole, the liquid outlet is connected to a lower tube 231, and the drain valve 2311 is disposed on the lower tube 231.

Wherein, upper cover 21 and lower cover 23 enclose with holding a section of thick bamboo 22 and close the cavity that constitutes a test section of thick bamboo 2, and upper cover 21 and lower cover 23 and hold the ability between a section of thick bamboo 22 and dismantle sealing connection and can adopt current arbitrary mode to realize, the utility model discloses do not prescribe a limit to this. Generally, the upper cover 21 is integrally formed with the upper pipe 211, and the lower cover 23 is integrally formed with the lower pipe 231. The lower end surface of the support plate 3 described above abuts against the upper end surface of the lower cover 23, i.e., the top surface of the taper hole. Therefore, when the sieve tube filtering sample piece 4 needs to be replaced after the experiment is finished each time, the upper cover 21 and the lower cover 23 are taken down and then reinstalled, and the method is simple and convenient.

In order to facilitate the placement and support of the test cartridge 2, the whole test device further comprises a support frame 1, the support frame 1 comprises a bottom plate, two vertical support rods fixed on the bottom plate and two transverse support rods fixed between the two vertical support rods, the two vertical support rods are arranged at intervals in parallel, the two transverse support rods are arranged at intervals in parallel, and upper mounting holes and lower mounting holes which are coaxially arranged are formed in the two transverse support rods respectively. The test cylinder 2 is arranged between the two transverse support rods, the upper pipe body 211 penetrates through the upper mounting hole and extends upwards, the lower pipe body 231 penetrates through the lower mounting hole and extends downwards, and the measuring cylinder 9 is placed on the bottom plate. Wherein, generally two horizontal bracing pieces can dismantle fixedly with two vertical support bars to installation test section of thick bamboo 2.

Further, the specific process of testing by using the above evaluation testing device is as follows, including the following steps:

s1, preparing simulated sand with the same characteristic as the formation sand sample in the heavy oil well and simulated liquid with the same viscosity as the crude oil in the heavy oil well, and then uniformly mixing the simulated sand with the simulated liquid to obtain the simulated mortar.

Specifically, in practical application, the simulated sand and the simulated liquid are respectively similar to the characteristics of the formation sand sample and the viscosity of crude oil. Step S1 specifically includes the following steps:

after the formation sand sample is subjected to oil washing treatment, the particle size distribution of the formation sand sample is tested by adopting a screening method or a laser particle size analyzer, and then the shale content of the formation sand sample is calculated according to the logging data (the calculation is the prior art).

According to the particle size distribution and the mud content of the stratum sand sample, quartz sand with different particle sizes is mixed to prepare simulated sand which is similar to the characteristics of the stratum sand sample such as the particle size median, the separation coefficient, the mud content and the like.

The simulation liquid with the viscosity similar to that of crude oil is prepared by adopting high molecular viscosity increasing agents such as guanidine gum, CMC, PAC and the like and clear water.

Adding the simulated sand into the simulated liquid, fully stirring and mixing to prepare the simulated mortar with the concentration of 30-60%. The mortar concentration can enable the thickness of the formed sand bridge to be moderate, and the test accuracy is improved.

S2, closing the drain valve 2311, pouring the simulated mortar into the cavity of the test cylinder 2, and adopting the same mortar concentration in the same group of comparative experiments.

And S3, conveying gas with a certain pressure into the chamber through the gas source 8, wherein the same pressure value is adopted in the same group of comparison experiments. Wherein, the gas is generally transported by opening the pressure regulating valve 7 and regulating the pressure to 0.2 to 10 MPa.

S4, opening the drain valve 2311, simultaneously pressing the timer, closing the timer when the liquid outlet stops draining liquid, and recording the time t of the timer.

And S5, recording the amount of the simulated mortar in the measuring cylinder 9, and analyzing the recorded amount to obtain the sand content of the simulated mortar in the measuring cylinder 9. Specifically, the simulated mortar in the measuring cylinder 9 is filtered by filter paper, and then is dried, weighed and subjected to particle size analysis to obtain the sand content ratio η.

S6, replacing the screen filtering sample piece 4 with different types and/or sand blocking precision, and repeating the steps S2 to S5. Wherein, when changing sieve pipe and filtering appearance spare 4 at every turn, can only change its type according to the experiment needs, only change its sand blocking precision, also can change its type and sand blocking precision simultaneously.

S7, evaluating the sand control effect of the screen pipe filtering sample piece 4 under the corresponding stratum sand sample condition according to the sand content eta of the simulated mortar in the measuring cylinder 9 and the time t of the timer during each experiment.

Wherein, the smaller the sand content ratio eta of the simulated mortar in the measuring cylinder 9 and the time t of the timer are, the better the sand control effect is, and the sand content ratio eta is generally required to be less than 0.03-0.05%. The timer time t reflects the ability of the screen or gravel layer to allow fluid to pass through, with a smaller timer time t indicating a screen or filter layer that is less likely to become plugged with formation sand.

In conclusion, the evaluation testing device in the embodiment can more accurately, more quickly, more efficiently and more cost-effectively select the sand control screen pipe and determine the size of the gravel.

The above are merely exemplary embodiments of the present invention, and are not intended to limit the scope of the present invention. Any person skilled in the art should also realize that such equivalent changes and modifications can be made without departing from the spirit and principles of the present invention.

Claims (10)

1. A thick oil well sand control effect evaluation testing device is characterized by comprising a testing cylinder which is vertically arranged and is provided with a cavity;

the upper end of the test cylinder is connected with an air source capable of conveying air into a cavity of the test cylinder, a support plate with a plurality of through holes is horizontally arranged near the bottom of the cavity, a certain gap is reserved between the support plate and the bottom surface of the cavity, a sieve tube filtering sample piece is arranged above the support plate, and uniformly mixed simulation mortar is filled in the cavity and above the sieve tube filtering sample piece;

the lower end face of the test cylinder is provided with a liquid outlet communicated with the space formed by the gap, a liquid discharge valve is arranged at the liquid outlet, and a measuring cylinder is arranged below the test cylinder and corresponding to the liquid outlet.

2. The sand control effect evaluation test device for thick oil wells according to claim 1,

and a gravel layer is filled above the screen pipe filtering sample piece.

3. The sand control effect evaluation test device for thick oil wells according to claim 1,

the inner wall of the lower end of the test tube is positioned below the supporting plate to form a taper hole with a diameter gradually reduced downwards and communicated with the liquid outlet.

4. The sand control effect evaluation test device for thick oil wells according to claim 1,

the cross-sectional area of the liquid outlet is larger than the flow area of the sieve tube filtering sample piece.

5. The sand control effect evaluation test device for thick oil wells according to claim 1,

and a limiting convex ring with a reduced diameter is formed on the inner wall of the testing cylinder and above the sieve tube filtering sample piece.

6. The sand control effect evaluation test device for thick oil wells according to claim 5,

a sealing ring is clamped between the limiting convex ring and the sieve tube filtering sample piece, the upper end face of the sealing ring abuts against the lower end face of the limiting convex ring, and the lower end face of the sealing ring abuts against the edge of the upper end face of the sieve tube filtering sample piece.

7. The sand control effect evaluation test device for thick oil wells according to claim 1,

the drain valve is a butterfly valve.

8. The sand control effect evaluation test device for thick oil wells according to claim 3,

the air source comprises an air storage bottle, the air storage bottle is connected with the upper end of the testing cylinder through a pipeline, a pressure regulating valve is arranged on the pipeline, and a pressure gauge is connected with the upper end of the testing cylinder.

9. The sand control effect evaluation test device for thick oil wells according to claim 8, wherein the test cylinder comprises a containing cylinder with openings at both ends, an upper cover and a lower cover;

an upper pipe body vertically penetrating through the upper cover is arranged in the upper cover, the upper pipe body is communicated with the cavity, the upper cover can be detachably and hermetically connected with the upper end of the containing cylinder, the pressure gauge is connected with the upper end of the upper pipe body, and the side wall of the upper end of the upper pipe body is provided with an air inlet and is connected with the pipeline;

the lower cover and the lower end of the containing cylinder can be detachably and hermetically connected, the inner wall of the lower cover forms the taper hole, the liquid outlet is downwards connected with a lower pipe body, and the liquid discharge valve is arranged on the lower pipe body.

10. The sand control effect evaluation test device for thick oil wells according to claim 9,

the support frame comprises a bottom plate, two vertical support rods fixed on the bottom plate and two transverse support rods fixed between the two vertical support rods, the two vertical support rods are arranged in parallel at intervals, the two transverse support rods are arranged in parallel up and down at intervals, and an upper mounting hole and a lower mounting hole which are coaxially arranged up and down are respectively formed in the two transverse support rods;

the test cylinder is arranged between the two transverse support rods, the upper pipe body penetrates through the upper mounting hole and extends upwards, the lower pipe body penetrates through the lower mounting hole and extends downwards, and the measuring cylinder is placed on the bottom plate.

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