CN215894309U

CN215894309U - Fracturing fluid reservoir damage evaluation device

Info

Publication number: CN215894309U
Application number: CN202121389621.5U
Authority: CN
Inventors: 张颖; 余维初; 丁飞; 周东魁; 舒文明; 吴爱斌; 宋永涛; 李玉敏; 余镭
Original assignee: Yangtze University
Current assignee: Modern Oil Sience & Technology Co ltd Of Jingzhou
Priority date: 2021-06-22
Filing date: 2021-06-22
Publication date: 2022-02-22
Anticipated expiration: 2031-06-22

Abstract

The utility model relates to the technical field of chemical experimental equipment for oil and gas field application, in particular to a damage evaluation device for a fracturing fluid reservoir, which consists of a liquid storage tank, a chromatography device, a bracket, a receiving container and a height regulator; according to the utility model, by utilizing the characteristics of different time and speed of different liquids passing through the porous medium in the filtration of the porous medium, silica gel particles with different particle sizes are laid on the chromatographic column to form a porous structure, the structure of an unconventional oil and gas reservoir is simulated to evaluate the damage degree of the fracturing fluid to the reservoir, and the fracturing fluid capable of realizing the protection of the unconventional oil and gas reservoir is screened out. The experiment of the utility model is carried out at normal temperature and normal pressure, the experiment risk of high-pressure displacement is avoided, liquid can be automatically added into the chromatographic column by adjusting the height of the liquid storage tank, the liquid in the chromatographic column cannot shake, the experiment error caused by direct liquid adding is avoided, the operation is simple, the control is convenient, and the problems of long experiment period and high experiment cost in the existing reservoir injury evaluation means are solved.

Description

Fracturing fluid reservoir damage evaluation device

Technical Field

The utility model relates to the technical field of chemical experimental equipment for oil and gas field application, in particular to a fracturing fluid reservoir damage evaluation device.

Background

Large-scale volume fracturing is one of the most effective development means of the conventional unconventional oil and gas resources, and in order to obtain the maximum reservoir transformation volume, a large amount of fracturing fluid is injected into a stratum during the fracturing construction process to form an artificial fracture. The fracturing fluid is formed by mixing a plurality of additives according to a certain proportion, the performance of the fracturing fluid is a key factor of fracturing work and cost, and meanwhile, the fracturing fluid is related to whether effective supporting fractures can be formed in a reservoir stratum or not, the damage is reduced, and the subsequent yield increasing effect is achieved. The fracturing fluid has dual properties, so that the reservoir forms a crack to improve the seepage capability, meanwhile, the reservoir is invaded to break the original balance to cause damage to a certain degree, and along with the increase of the fracturing scale and times, the damage range of the fracturing fluid filtrate on the reservoir is enlarged from a single near-wellbore area to the influence on the overall development effect. Although fracturing is an important development and stimulation measure for tight oil production, fracturing fluid serving as a core causes various damages to a stratum in the fracturing process, so that the damage degree of the fracturing fluid to a reservoir is one of important indexes influencing the performance of the fracturing fluid.

The damage of the fracturing fluid of an unconventional oil and gas reservoir is divided into damage to a base layer and damage to supporting fractures according to action positions, the physical modeling experimental study for evaluating the damage degree of the fracturing fluid to the reservoir at present mainly utilizes an artificial rock core, a natural rock core or a sand-packed pipe as a model to evaluate the change of permeability before and after damage, although the method can comprehensively reflect the damage condition of the fracturing fluid to the reservoir, the experimental period is long, the steps are complicated, and the cost of experimental materials is high.

Disclosure of Invention

The utility model aims to provide a fracturing fluid reservoir damage evaluation device which adopts the principle that different liquids in the filtration principle pass through porous media in different time and speed and the characteristic that silica gel particles cannot expand when being soaked in the liquids, forms a porous structure by paving the silica gel particles with different particle sizes, simulates a pore roar structure of an unconventional oil and gas reservoir, removes the influence of the fracturing fluid on the hydration and expansion damage of a reservoir matrix, mainly evaluates the damage conditions of the fracturing fluid on the pore roar and supporting cracks of the unconventional oil and gas reservoir, and evaluates the damage degree of the fracturing fluid on the unconventional oil and gas reservoir by testing the time and the flow of the different fracturing fluids passing through the silica gel pores.

The utility model realizes the purpose through the following technical scheme:

the utility model provides a fracturing fluid reservoir damage evaluation device, it comprises reservoir, pipette, chromatography device, support, receiving vessel and altitude controller, its characterized in that: the support is composed of an installation clamp, a base A and a support rod, the support rod is fixedly arranged on one side of the base, and the installation clamp is arranged at the upper end of the support rod; the middle part of the base A is provided with a height adjuster, and the upper end of the height adjuster is provided with a mounting plate; the chromatographic device consists of silica gel particles, a sand chip, a valve and a chromatographic column, wherein the chromatographic column is arranged on an installation clamp of the bracket, the sand chip is arranged at the lower part of the chromatographic column, the silica gel particles are arranged in the chromatographic column at the upper part of the sand chip, and the valve is arranged at the bottom of the chromatographic column; the receiving container is placed on the base A, and the upper opening of the receiving container is opposite to the lower part of the chromatographic column; the liquid storage tank is placed on the mounting plate, and the liquid storage tank is communicated with the chromatographic column through a liquid suction pipe.

The height adjuster consists of a platform, a base B, two rotary supporting rods which are crossed into a scissor shape and an adjusting handle, wherein the lower ends of the two rotary supporting rods which are crossed into the scissor shape are placed on the base B, the platform is arranged at the upper ends of the rotary supporting rods, one ends of the two rotary supporting rods are respectively fixed at one sides of the base B and the platform through a fixing seat B, the other ends of the two rotary supporting rods are respectively arranged in grooves at the other sides of the base B and the platform through rollers in an abutting mode, the adjusting handle is respectively arranged on the base B and the platform at the side through a spiral structure, and one end of the adjusting handle is contacted with the rollers through an adjusting block; the middle parts of the two rotary supporting rods can rotate around the pin shaft, and the two ends of the two rotary supporting rods can rotate around the fixing seat B and the roller respectively.

The chromatographic column and the receiving container are respectively provided with scale marks.

The bottom area of the liquid storage groove is 5-10 times of the area of the circle at the maximum diameter of the chromatographic column.

The silica gel particles respectively consist of particles with the particle sizes of 100-115 meshes, 120-135 meshes, 140-165 meshes and 170-200 meshes, and the proportion of the four particles is 25 percent of the mass ratio.

The reservoir be the cuboid shape, the one end of pipette is fixed on the reservoir be close to one side of chromatography device through the fixing base.

The use method of the fracturing fluid reservoir damage evaluation device comprises the following steps:

firstly, designing an experimental scheme according to geological data of a well site, wherein the experimental scheme comprises the following contents: the formula and performance index of the fracturing fluid, the particle size and proportion of the laid silica gel particles, and the time and volume of fluid passing through the silica gel chromatographic column;

step two, preparation and performance test of the fracturing fluid are carried out: the performance indexes comprise density, viscosity and pH value;

thirdly, sieving and weighing the silica gel particles, and selecting 5g of four silica gel particles of 100-115 meshes, 120-135 meshes, 140-165 meshes and 170-200 meshes according to an experimental scheme;

step four, taking four 20mL beakers, respectively adding 10mL deionized water into each beaker, and respectively placing the four silica gel particles into the four beakers under the condition of stirring by a glass rod;

fifthly, after fully stirring for 2min, putting the beaker into an ultrasonic cleaner for degassing for 5 min;

sixthly, pouring the mixture of the 170-plus-200-mesh silica gel particles and water into the chromatographic column, washing the beaker and the tube wall of the chromatographic column with 10mL of deionized water, repeating for 3 times, and opening a valve to allow the deionized water in the chromatographic column to flow out after all the silica gel particles fall into the bottom of the chromatographic column;

seventhly, according to the operation of the sixth step, silica gel particles of 140-mesh 165-mesh, 120-mesh 135-mesh and 100-mesh 115-mesh are added into the chromatographic column layer by layer respectively;

eighthly, measuring 2L of the prepared fracturing fluid prepared in the second step, and degassing the prepared fracturing fluid by using an ultrasonic cleaner;

the ninth step, slowly pouring degassed fracturing fluid into the prepared chromatographic column to a scale mark with a specified height, pouring the rest degassed fracturing fluid into a liquid storage tank, and then adjusting a height regulator to enable the liquid level height in the liquid storage tank and the liquid level height of the chromatographic column to reach the same level of the scale mark;

step ten, filling the liquid suction pipe with fracturing fluid, rapidly inserting two ends of the liquid suction pipe below the liquid levels of the liquid storage tank and the chromatographic column respectively, and fixing one end of the liquid suction pipe on one side of the liquid storage tank close to the chromatographic device through a fixing seat A;

step ten, opening a valve, and measuring the volume of the liquid flowing through the silica gel particles once every 5-10min by a receiving container;

step twelve, after the valve is opened, observing the chromatographic column of the chromatographic device, and if the liquid level in the chromatographic column is obviously reduced, adjusting the height of the liquid storage tank in time through a height adjuster to maintain the liquid level in the chromatographic column at the original height;

step thirteen, respectively testing the reservoir damage of different fracturing fluids, and recording the liquid volume of different fracturing fluids passing through the silica gel particle porous medium in each 5-10min time period;

fourteenth, calculating the volume of the liquid passing through the silica gel column in each time period into the flow velocity of the corresponding time, calculating the flow injury ratio in different time periods through the following formula, and determining the injury degree of the fracturing fluid to the reservoir through the flow injury ratio;

in the formula, R_v-flow injury ratio,%; v₁-flow in the first time period, mL/min; v_n-flow in the nth time period, mL/min.

Compared with the prior art, the utility model has the beneficial effects that:

the fracturing fluid reservoir damage evaluation device utilizes the principle that different liquids pass through a porous medium in the filtering principle of the porous medium, the time and the speed of the liquids are different, and silica gel particles are soaked in the liquids and cannot expand, the porous structure is formed by paving the silica gel particles with different particle sizes, the pore roar structure of an unconventional oil and gas reservoir is simulated, the influence of the fracturing fluid on the hydration expansion damage of a reservoir matrix is eliminated, the damage condition of the fracturing fluid on the pore roar and cracks of the reservoir is simulated by mainly evaluating the pore damage condition of the liquids to the porous medium, the damage condition of the fracturing fluid on the reservoir is screened out by evaluating the damage degree of the fracturing fluid to the reservoir, and the fracturing fluid capable of protecting the unconventional oil and gas reservoir is screened out. The experiment of the utility model is carried out at normal temperature and normal pressure, thus avoiding the experiment risk of high-pressure displacement; the porous structure of the reservoir is simulated by adopting the gaps for accumulating the silica gel particles, so that the cost of experimental materials is greatly reduced and the experimental period is shortened compared with that of an experiment adopting a rock core or a sand filling pipe; according to the utility model, the principle that the liquid levels at the two ends of the communication device are consistent is utilized, so that liquid in the liquid storage tank is automatically added into the chromatographic column, and the liquid storage tank adopts a cubic water tank with a large bottom area, so that the liquid level in the chromatographic column is prevented from rapidly falling; the reservoir is placed on the mounting panel that highly can freely adjust, can be to the automatic liquid feeding in the chromatographic column through the height of adjusting the reservoir, can not arouse rocking of liquid in the chromatographic column simultaneously, makes the liquid in the chromatographic column remain the level at a constant voltage all the time, convenient operation has avoided the experimental error that direct liquid feeding caused moreover. The method is simple and rapid to operate, convenient to control, safe, reliable and reasonable in structure, and solves the problems of long experimental period, complex steps and high experimental material cost in the existing reservoir damage evaluation means.

Drawings

FIG. 1 is a schematic structural diagram of a damage evaluation device for a fracturing fluid reservoir;

FIG. 2 is a schematic vertical cross-sectional view of the laydown of the silica gel particles of FIG. 1;

FIG. 3 is a schematic view of the height adjuster;

FIG. 4 is a graphical representation of a comparison of flow injury ratios of three fracturing fluids.

In the figure: 1. a liquid storage tank 101, a fixing seat A, 2, a liquid suction pipe, 3, a chromatography device 301, silica gel particles 302, a sand core sheet 303, a valve 304, a chromatography column 4, a support 401, a mounting clamp 402, a base A, 403, a support rod 5, a receiving container 6, a height adjuster 601, a platform 602, a base B, 603, a rotating support rod 604, a fixing seat B, 605, a pin shaft 606, an adjusting handle 607, an adjusting block 608, a roller, 7 and a mounting plate.

Detailed Description

The device for evaluating the damage of the fracturing fluid reservoir utilizes silica gel particles 301 to form a porous structure simulated reservoir fracture after being filled in a chromatographic column 304, solid phase residues in the fracturing fluid can be remained in the silica gel particles 301 in the chromatographic column 304, the flowing capacity of the chromatographic column 304 is obviously reduced, the damage degree of the fracturing fluid to the chromatographic column 304 is quantitatively evaluated through the change of the flow velocity of the fracturing fluid in the chromatographic column 304, and then the damage degree of different fracturing fluid systems to the reservoir can be quickly analyzed.

The fracturing fluid reservoir damage evaluation device is composed of a reservoir 1, a pipette 2, a chromatography device 3, a support 4, a receiving container 5 and a height adjuster 6, wherein the support 4 is composed of an installation clamp 401, a base A402 and a support rod 403, the support rod 403 is fixedly arranged on one side of the base A402, and the installation clamp 401 is arranged at the upper end of the support rod 403; the middle part of the base A402 is provided with a height adjuster 6, and the upper end of the height adjuster 6 is provided with a mounting plate 7; the chromatography device 3 comprises silica gel particles 301, a sand core piece 302, a valve 303 and a chromatography column 304, wherein the chromatography column 304 is arranged on an installation clamp 401 of the bracket 4, the lower part of the chromatography column 304 is provided with the sand chip 302, the chromatography column 304 on the upper part of the sand core piece 302 is internally provided with the silica gel particles 301, the silica gel particles 301 respectively comprise particles with the particle diameters of 100-; the bottom of the chromatographic column 304 is provided with a valve 303; the receiving container 5 is placed on the base A402, the upper opening of the receiving container 5 faces the lower part of the chromatographic column 304, the chromatographic column 304 and the receiving container 5 are respectively provided with scale marks, and the scale marks of the receiving container 5 can read the volume of the liquid passing through the silica gel particles 301 within a set time in real time. The bottom area of the liquid storage tank 1 is 5-10 times of the area of a circle at the maximum diameter of the chromatographic column 304; the liquid storage tank 1 is placed on the mounting plate 7, and the liquid storage tank 1 is communicated with the chromatographic column 304 through the liquid suction pipe 2; the liquid storage tank 1 is in a cuboid shape, and one end of the liquid suction pipe 2 is fixed on one side of the liquid storage tank 1 close to the chromatography device 3 through a fixing seat A101; (see FIGS. 1-2); the liquid suction pipe 2 keeps the same height between the liquid storage tank 1 and the chromatography device 3 through the principle of a communicating vessel, the liquid storage tank 1 is a cubic container with a larger bottom area, liquid in the container is communicated with the chromatography column 304 through the liquid suction pipe 2, so that the liquid level height in the chromatography column 304 cannot be obviously changed, and the aim of avoiding the need of frequently supplementing liquid in the chromatography column 304 to maintain the liquid level height in the experiment process is fulfilled.

The height adjuster 6 is composed of a platform 601, a base B602, two rotary supporting rods 603 which are crossed into a scissor shape and an adjusting handle 606, the lower ends of the two rotary supporting rods 603 which are crossed into the scissor shape are placed on the base B602, the platform 601 is arranged at the upper end of the rotary supporting rods 603, one ends of the two rotary supporting rods 603 are respectively fixed at one side of the base B602 and one side of the platform 601 through a fixing seat B604, the other ends of the two rotary supporting rods 603 are respectively leaned against and arranged in grooves at the other sides of the base B602 and the platform 601 through a roller 608, the adjusting handle 606 is respectively arranged on the base B602 and the platform 601 at the side through a spiral structure, and one end of the adjusting handle 606 is contacted with the roller 608 through an adjusting block 607; the middle parts of the two rotary supporting rods 603 can rotate around a pin 605, and the two ends of the two rotary supporting rods 603 can respectively rotate around the fixed seat B604 and the roller 608. (see FIG. 3). The height adjuster 6 can adjust the height of the liquid level in the liquid storage tank 1, so that the liquid level in the chromatography device 3 is supplemented, the liquid above the silica gel particles 301 is always kept in a constant pressure state, and meanwhile, experimental errors caused by direct liquid adding into the liquid storage tank 1 or the chromatographic column 304 are avoided.

firstly, designing an experimental scheme according to geological data of a well site, wherein the experimental scheme at least comprises the following contents: the formula and performance index of the fracturing fluid, the particle size and proportion of the laid silica gel particles, and the time and volume of fluid passing through the silica gel chromatographic column;

thirdly, sieving and weighing the silica gel particles 301, and selecting 5g of four silica gel particles 301 with 100-mesh, 115-mesh, 120-mesh, 135-mesh, 140-mesh, 165-mesh and 170-mesh, 200-mesh according to an experimental scheme;

step four, taking four 20mL beakers, respectively adding 10mL deionized water into each beaker, and respectively placing the four silica gel particles 301 into the four beakers under the condition of stirring by a glass rod;

sixthly, pouring the mixture of the 170-200-mesh silica gel particles 301 and water into the chromatographic column 304, washing the beaker and the tube wall of the chromatographic column 304 with 10mL of deionized water, repeating the steps for 3 times, and opening the valve 303 to allow the deionized water in the chromatographic column 304 to flow out after all the silica gel particles 301 fall into the bottom of the chromatographic column 304;

seventhly, according to the operation of the sixth step, silica gel particles of 140-165 meshes, 120-135 meshes and 100-115 meshes are added into the chromatographic column 304 layer by layer respectively;

step nine, slowly pouring degassed fracturing fluid into the prepared chromatographic column 304 to a scale mark with a specified height, pouring the rest degassed fracturing fluid into a liquid storage tank 1, and then adjusting a height regulator 6 to enable the liquid level height in the liquid storage tank 1 and the liquid level height of the chromatographic column 304 to reach the same level of scale mark;

step ten, filling the pipette 2 with fracturing fluid, rapidly inserting two ends of the pipette 2 below the liquid levels of the liquid storage tank 1 and the chromatographic column 304 respectively, and fixing one end of the pipette 2 on one side of the liquid storage tank 1 close to the chromatographic device 3 through a fixing seat A101;

step ten, opening a valve 303, and metering the volume of the liquid flowing through the silica gel particles 301 once through a receiving container 5 every 5-10 min;

step twelve, after the valve 303 is opened, the chromatographic column 304 of the chromatographic device 3 is observed, and if the liquid level in the chromatographic column 304 is obviously reduced, the height of the liquid storage tank 1 needs to be adjusted in time through the height adjuster 6, so that the liquid level in the chromatographic column 304 is maintained at the original height; when the height of the liquid storage tank 1 is adjusted, the adjusting block 607 moves in the grooves of the base B602 and the platform 601 by rotating the adjusting handle 606 of the height adjuster 6, so that the roller 608 rolls in the corresponding groove, the height of the mounting plate 7 is adjusted by adjusting the included angle of the two rotating support rods 603, and the height of the liquid storage tank 1 is adjusted by the mounting plate 7;

step thirteen, respectively testing the reservoir damage of different fracturing fluids, and recording the liquid volume of different fracturing fluids passing through the silica gel particle 301 porous medium in each 5-10min time period;

The following is a concrete example of evaluating damage of fracturing fluid reservoir

(1) Preparation of silica gel porous medium

Weighing 5g of 100-mesh, 120-mesh, 150-mesh and 190-mesh silica gel particles 301 respectively; taking 4 beakers with the volume of 20mL, adding 10mL of deionized water into each beaker, and respectively putting the four silica gel particles 301 into the 4 beakers under the stirring of a glass rod; stirring for 2min, degassing for 5 min; pouring the mixture of 190-mesh silica gel particles 301 and water into the chromatographic column 304, washing the beaker and the wall of the chromatographic column 304 with 10mL of deionized water, repeating for 3 times until all the silica gel particles 301 fall into the bottom of the chromatographic column 304, and opening the valve 303 to allow the deionized water in the chromatographic column 304 to flow out; repeating the previous operation, and adding the 150-mesh, 120-mesh and 100-mesh silica gel particles into the chromatographic column 304 layer by layer.

(2) Preparation of fracturing fluid

Measuring three parts of deionized water, 2L each, and preparing the deionized water, the drag reducer and the additive into No. 1, No. 2 and No. 3 fracturing fluids respectively; wherein the formula of the No. 1 fracturing fluid is deionized water, 0.1 percent of water-based drag reducer and 0.2 percent of multifunctional additive; the formula of the No. 2 fracturing fluid is deionized water, 0.1 percent of oil-based drag reducer and 0.2 percent of multifunctional additive; the formula of No. 3 fracturing fluid is deionized water, 0.1% of powder drag reducer and 0.2% of multifunctional additive; and degassing the prepared No. 1, No. 2 and No. 3 fracturing fluids by using an ultrasonic cleaner after the preparation is finished.

(3) Reservoir damage testing

Slowly pouring degassed fracturing fluid into the prepared chromatographic column 304 to a scale mark with a specified height, and pouring the rest degassed fracturing fluid into the reservoir 1 to enable the liquid level height in the reservoir 1 and the liquid level height of the chromatographic column 304 to reach the same level of scale mark;

filling the pipette 2 with fracturing fluid, rapidly inserting two ends of the pipette 2 below the liquid levels of the liquid storage tank 1 and the chromatographic column 304 respectively, and fixing the pipette 2 by using a fixing seat A101;

opening the valve 303, and metering the volume of the liquid flowing through the silica gel particles 301 by using the receiving container 5 every 5 min;

if the liquid level in the column 304 is lowered significantly, the height of the reservoir 1 needs to be adjusted in time to maintain the liquid level in the column 304 at the original height.

(4) Data processing

The flow injury ratio data for the different samples tested are shown in Table 1 and FIG. 4 below

Table 1 is a flow injury ratio data table of No. 1, No. 2 and No. 3 fracturing fluids

The influence of the fracturing fluid on the permeability of the matrix of the rock core is tested by referring to the national oil and gas industry standard SY/T5358-2010 reservoir sensitivity flow experiment evaluation method, and the initial permeability of the rock sample is determined by adopting the initial test fluid. And (3) after the initial permeability of the rock sample is measured, displacing with different fracturing fluid fluids, keeping the displacement speed consistent with the initial flow rate, displacing by 10-15 times of the pore volume, stopping displacing, keeping the confining pressure and the temperature unchanged, enabling the intermediate fracturing fluid to fully react with rock minerals for 2 hours, and measuring the permeability after damage. The obtained core permeability damage data are shown in table 2.

Table 2 is a table of damage rate data of three kinds of fracturing fluids No. 1, 2 and 3 to rock core permeability

As can be seen from fig. 4, the fracture fluid flow injury ratios of nos. 1, 2, and 3 are 50%, 80%, and 100%, respectively. The core damage data and the flow damage ratio data are compared to know that the core damage data and the flow damage ratio data have positive correlation, namely the higher the core damage ratio is, the larger the flow damage ratio is.

While the foregoing is directed to embodiments of the present invention, other and further embodiments of the utility model may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.

Claims

1. The utility model provides a fracturing fluid reservoir damage evaluation device, it comprises reservoir (1), pipette (2), chromatography device (3), support (4), receiving vessel (5) and altitude controller (6), its characterized in that: the support (4) consists of a mounting clamp (401), a base A (402) and a support rod (403), the support rod (403) is fixedly arranged on one side of the base A (402), and the mounting clamp (401) is arranged at the upper end of the support rod (403); the middle part of the base A (402) is provided with a height adjuster (6), and the upper end of the height adjuster (6) is provided with a mounting plate (7); the chromatography device (3) is composed of silica gel particles (301), a sand core sheet (302), a valve (303) and a chromatography column (304), the chromatography column (304) is installed on an installation clamp (401) of the support (4), the sand core sheet (302) is installed on the lower portion of the chromatography column (304), the silica gel particles (301) are installed in the chromatography column (304) on the upper portion of the sand core sheet (302), and the valve (303) is installed at the bottom of the chromatography column (304); the receiving container (5) is placed on the base A (402), and the upper opening of the receiving container (5) is opposite to the lower part of the chromatographic column (304); the liquid storage tank (1) is placed on the mounting plate (7), and the liquid storage tank (1) is communicated with the chromatographic column (304) through the liquid suction pipe (2).

2. A fracturing fluid reservoir damage evaluation device according to claim 1, wherein: the height adjuster (6) is composed of a platform (601), a base B (602), two rotary supporting rods (603) which are crossed into a scissor shape and an adjusting handle (606), the lower ends of the two rotary supporting rods (603) which are crossed into the scissor shape are placed on the base B (602), the platform (601) is installed at the upper end of each rotary supporting rod (603), one ends of the two rotary supporting rods (603) are respectively fixed at one side of the base B (602) and one side of the platform (601) through a fixing seat B (604), the other ends of the two rotary supporting rods (603) are respectively arranged in grooves at the other sides of the base B (602) and the platform (601) through rollers (608), the adjusting handles (606) are respectively installed on the base B (602) and the platform (601) at the side through spiral structures, and one ends of the adjusting handles (606) are contacted with the rollers (608) through adjusting blocks (607); the middle parts of the two rotary supporting rods (603) can rotate around a pin shaft (605), and the two ends of the two rotary supporting rods (603) can respectively rotate around a fixed seat B (604) and a roller (608).

3. A fracturing fluid reservoir damage evaluation device according to claim 1, wherein: the chromatographic column (304) and the receiving container (5) are respectively provided with scale marks.

4. A fracturing fluid reservoir damage evaluation device according to claim 1, wherein: the bottom area of the reservoir (1) is 5-10 times of the area of a circle at the maximum diameter of the chromatographic column (304).

5. A fracturing fluid reservoir damage evaluation device according to claim 1, wherein: the liquid storage tank (1) is in a cuboid shape, and one end of the liquid suction pipe (2) is fixed on one side, close to the chromatography device (3), of the liquid storage tank (1) through a fixing seat A (101).