WO2021203611A1 - Method for determining change in nanoscale pore structure, and use thereof - Google Patents

Abstract

Disclosed are a method for determining a change in a nanoscale pore structure, and the use thereof. The determination method comprises: a, putting a nanoscale pore structure sample which has been subjected to vacuum degassing into liquid nitrogen to obtain an isothermal adsorption curve, which shows the amount of nitrogen absorbed by the sample as the relative pressure P/P₀ changes; b, according to the isothermal adsorption curve, calculating the specific surface area (SSA) of the sample by utilizing a BET specific surface area formula; c, according to an NLDFT density function theory method, obtaining the sum PV of pore volumes of pores of different scales in the sample; and d, determining the influence of a crushing process on the nanoscale pore structure according to an SSA/PV value following changes in a crushing mesh number. The determination method can accurately determine the influence of a sample fabrication damage process on the nanoscale pore structure of a tight reservoir, and can be used for determining the error influence, brought about by a change in a pore structure during sample fabrication, on a research result in a traditional tight reservoir nanoscale pore qualitative and quantitative research method.

Description

一种纳米级孔隙结构变化的判断方法及应用A method for judging nano-scale pore structure changes and its application

本发明专利申请要求于2020年04月10日提交的中国专利申请NO.CN202010281035.2的优先权。在先申请的公开内容通过整体引用并入本申请。The patent application for this invention claims the priority of the Chinese patent application No. CN202010281035.2 filed on April 10, 2020. The disclosure of the earlier application is incorporated into this application by reference in its entirety.

技术领域Technical field

本方案涉及到一种纳米级孔隙结构变化的判断方法及应用。This scheme involves a method for judging the change of nano-scale pore structure and its application.

背景技术Background technique

随着全球能源需求的不断增长以及油气开发技术的不断提高，致密油气资源逐渐成为许多国家勘探和开发的重点。石油和天然气主要在致密储层（例如钻井开采过程中获得的页岩岩心）中的纳米级孔缝***赋存与渗流，因此对致密储层的孔缝***进行有效合理的评价和判断对于致密油气的勘探和开发具有重要意义。With the continuous growth of global energy demand and the continuous improvement of oil and gas development technology, tight oil and gas resources have gradually become the focus of exploration and development in many countries. Oil and natural gas are mainly stored and seeped in the nano-scale pore and fracture system in tight reservoirs (such as shale cores obtained during drilling and mining). Therefore, effective and reasonable evaluation and judgment of the pore and fracture system of tight reservoirs are important for tight reservoirs. The exploration and development of oil and gas is of great significance.

多孔介质是由许多孔隙和固体基质组成的，孔隙发育在固体基质中。多孔介质的比表面积是单位质量的多孔介质所具有的总面积；孔容即单位质量多孔介质所具有的细孔总容积；孔径分布是指多孔介质中存在的各级孔径按数量或体积计算的百分率。多孔介质的微观孔隙可以划分为三类：微孔（<2nm），介孔（2-50nm），宏孔（>50nm的孔缝）。现有的多孔介质中孔隙表征实验方法包括低温氮气吸附法和压汞法等，主要通过其测得的比表面积、孔容以及孔径分布等参数可以直接反映多孔介质中微观孔隙的一些特征。致密储层即为一种多孔介质，在现有的孔隙表征实验方法的基础上，通常通过改变不同实验条件，如测量不同岩性、不同目数、不同温压等条件下致密储层微观孔隙的表征参数，进行横纵向对比，来间接反映不同的实验条件对致密储层微观孔隙结构产生的影响。目前我们常用一些典型的岩石力学参数，如杨氏模量、泊松比来评价致密储层中裂缝发育的难易程度。但是，上述方法均存在忽略了制样损伤过程所造成的孔隙结构变化对致密储层微观孔隙的定性与定量研究产生的误差影响。因此，建立一种可以判断致密储层纳米级孔隙在结构损伤过程中产生的微观孔隙结构变化的方法具有重要意义。Porous media is composed of many pores and solid matrix, and the pores develop in the solid matrix. The specific surface area of a porous medium is the total area of the porous medium per unit mass; the pore volume is the total volume of pores per unit mass of the porous medium; the pore size distribution refers to the number or volume of the various pore sizes in the porous medium. percentage. The microscopic pores of porous media can be divided into three categories: micropores (<2nm), mesopores (2-50nm), and macropores (pores >50nm). Existing experimental methods for characterizing pores in porous media include low-temperature nitrogen adsorption method and mercury intrusion method. The measured specific surface area, pore volume, and pore size distribution can directly reflect some characteristics of microscopic pores in porous media. A tight reservoir is a kind of porous medium. Based on the existing pore characterization experiment method, different experimental conditions are usually changed, such as measuring the micro pores of tight reservoirs under different lithology, different mesh numbers, and different temperature and pressure conditions. The characterization parameters are compared horizontally and vertically to indirectly reflect the influence of different experimental conditions on the microscopic pore structure of tight reservoirs. At present, we often use some typical rock mechanics parameters, such as Young's modulus and Poisson's ratio, to evaluate the difficulty of fracture development in tight reservoirs. However, all of the above methods ignore the influence of errors caused by qualitative and quantitative research on the microscopic pores of tight reservoirs by ignoring the pore structure changes caused by the damage process of sample preparation. Therefore, it is of great significance to establish a method for judging the microscopic pore structure changes caused by nano-scale pores in tight reservoirs during structural damage.

技术问题technical problem

本方案提供一种纳米级孔隙结构变化的判断方法和应用。This solution provides a method and application for judging changes in nano-scale pore structure.

技术解决方案Technical solutions

该纳米级孔隙结构变化的判断方法，包括如下步骤：The method for judging the change of nano-scale pore structure includes the following steps:

a、将真空脱气后的纳米级孔隙结构的样品置于液氮中，在预先设定的多个压力值P下检测所述样品的氮气吸附量，获得所述样品的氮气吸附量随相对压力P/P ₀变化的等温吸附曲线，其中，P ₀为吸附温度下氮气的饱和蒸气压； a. Put the sample of the nano-scale pore structure after vacuum degassing in liquid nitrogen, and detect the nitrogen adsorption capacity of the sample under a plurality of preset pressure values P, and obtain the nitrogen adsorption capacity of the sample with the relative The adsorption isotherm curve of pressure P/P _{0 , where P 0} is the saturated vapor pressure of nitrogen at the adsorption temperature;

b、选取0.05<P/P ₀<0.35范围内的等温吸附曲线，通过斜率s和截距i求得单层吸附需要的氮气体积V _m；利用BET比表面积公式计算样品的比表面SSA；所述BET比表面积公式为SAA=（V _m×σ）/22400W，式中：σ为被吸附气体的截面积；W为真空脱气后的样品质量； b. Select the adsorption isotherm curve in the range of 0.05<P/P _{0 <0.35, and obtain the nitrogen volume V m} required for monolayer adsorption through the slope s and intercept i; use the BET specific surface area formula to calculate the specific surface SSA of the sample; The BET specific surface area formula is SAA=(V _m ×σ)/22400W, where: σ is the cross-sectional area of the adsorbed gas; W is the mass of the sample after vacuum degassing;

c、根据NLDFT密度函数理论法，分别计算出微孔、介孔和宏孔的孔体积，进而得到样品中所述微孔、介孔和宏孔的孔体积之和PV以及PV随粉碎目数的变化趋势；c. According to the NLDFT density function theory method, calculate the pore volume of micropores, mesopores and macropores respectively, and then obtain the sum of the pore volume PV of the micropores, mesopores and macropores in the sample and the change of PV with the number of crushing meshes. trend;

d、计算样品不同粉碎粒径下SSA/PV的值，根据所述SSA/PV的值随粉碎目数增加的变化趋势判断粉碎过程对样品中纳米级孔隙结构变化的影响。d. Calculate the value of SSA/PV under different crushed particle sizes of the sample, and judge the influence of the crushing process on the change of the nano-scale pore structure in the sample according to the change trend of the value of the SSA/PV with the increase of crushing mesh.

作为一种实施例，步骤a中所述真空脱气温度为90-120℃。As an example, the vacuum degassing temperature in step a is 90-120°C.

作为一种实施例，步骤a中所述真空脱气时间≥9h。As an example, the vacuum degassing time in step a is ≥9h.

作为一种实施例，步骤b中选取0.05<P/P ₀<0.35范围内的等温吸附曲线，通过斜率s和截距i求得单层吸附需要的氮气体积V _m。上述范围内的等温吸附曲线的选择，可以进一步减小判断方法的误差。 As an example, in step b, an _{adsorption isotherm curve in the range of 0.05<P/P 0 <0.35 is selected, and the nitrogen volume V m} required for monolayer adsorption is obtained from the slope s and the intercept i. The selection of the adsorption isotherm curve within the above range can further reduce the error of the judgment method.

作为一种实施例，步骤b中所述V _m与所述斜率s和所述截距i的关系为：V _m=1/（s+i）。所述V _m与0.05<P/P ₀<0.35范围内的等温吸附曲线的斜率s的关系为：s=（C-1）/(Vm×C)，式中：C为BET常数；所述V _m与0.05<P/P ₀<0.35范围内的等温吸附曲线的截距i的关系为：i=1/(Vm×C)，式中：C为BET常数；进而得出V _m=1/（s+i）。 As an embodiment, _{the relationship between the V m} and the slope s and the intercept i in _{step b is: V m} =1/(s+i). The relationship between the V _m and the slope s of the adsorption isotherm curve in the range of 0.05<P/P ₀ <0.35 is: s=(C-1)/(Vm×C), where: C is the BET constant; The relationship between V _m and the intercept i of the adsorption isotherm curve in the range of 0.05<P/P ₀ <0.35 is: i=1/(Vm×C), where C is the BET constant; and then V _m =1 /(S+i).

作为一种实施例，步骤c中选取0.01≤P/P ₀≤0.995范围内的数值，根据NLDFT密度函数理论法，通过ASiQ软件统计得到所述微孔、介孔和宏孔的孔体积。 As an example, in step c, _{a value in the range of 0.01≤P/P 0} ≤0.995 is selected, and the pore volume of the micropores, mesopores and macropores is obtained by statistics of the ASiQ software according to the NLDFT density function theory method.

作为一种实施例，步骤d中根据样品粉碎粒径由20目到200目时SSA/PV值的变化来判断样品中纳米级孔隙结构的变化。As an example, in step d, the change of the nano-scale pore structure in the sample is judged according to the change of the SSA/PV value when the particle size of the sample is crushed from 20 mesh to 200 mesh.

本方案还提供了所述判断方法用于判断制样损伤过程对致密储层纳米级孔隙结构影响的应用。本方案提供的纳米级孔隙结构变化的判断方法通过表征致密岩石微观孔隙的比表面积、孔容和孔径分布等参数，通过样品不同粉碎粒径下SSA/PV的变化可定性判断致密储层纳米级孔隙在结构损伤（即样品粉碎）过程中产生的微观孔隙结构变化，避免传统的致密储层纳米级孔隙定性与定量研究方法中忽略制样过程中孔隙结构变化对研究结果产生的误差影响。若所述SSA/PV值随着粉碎目数变化而产生了较为明显的变化，则可判断出制样损伤过程对致密储层纳米级孔隙结构产生了不同程度的影响。The solution also provides the application of the judgment method for judging the influence of the sample preparation damage process on the nano-scale pore structure of the tight reservoir. The method for judging nano-scale pore structure changes provided by this solution is to characterize the specific surface area, pore volume and pore size distribution of the microscopic pores of tight rocks, and to qualitatively judge the nano-level of tight reservoirs by the changes of SSA/PV under different crushed particle sizes of samples. The microscopic pore structure changes caused by pores in the process of structural damage (ie sample crushing) can avoid the error influence of pore structure changes on the research results that are ignored in the traditional qualitative and quantitative research methods of nano-scale pores in tight reservoirs. If the SSA/PV value changes significantly with the change of the crushing mesh, it can be judged that the sample preparation damage process has different degrees of influence on the nano-scale pore structure of the tight reservoir.

本方案还提供了所述判断方法用于判断致密储层纳米级孔隙结构样品的孔隙结构试验表征数据准确度中的应用。通过SSA/PV的变化率的大小判断出误差大小并进行矫正，可提高传统的致密储层纳米级孔隙定性与定量研究方法的准确性。The solution also provides the application of the judgment method for judging the accuracy of the pore structure test characterization data of the nano-scale pore structure sample of the tight reservoir. Judging the error size and correcting it through the change rate of SSA/PV can improve the accuracy of traditional qualitative and quantitative research methods of nano-scale pores in tight reservoirs.

作为一种实施例，若样品粉碎粒径由20目到200目时，SSA/PV值变小且SSA/PV值随粉碎目数变化的相关性系数R ²在0.6以上，则说明所述致密储层纳米级孔隙结构样品的所述孔隙结构试验表征数据存在一定的误差需要矫正。不同样品的SSA/PV值随粉碎目数变化的相关性系数R ²也有所差别，说明了还与样品的类型有关。石油和天然气主要在致密储层中的纳米级孔缝***赋存与渗流，若致密储层样品粉碎粒径由20目到200目时SSA/PV值变小且SSA/PV值随粉碎目数变化的相关性系数R ²在0.6以上，则传统的致密储层纳米级孔隙结构试验表征数据的检测存在的误差会影响甚至误导对致密储层的孔缝***进行有效合理评价和判断，不利于油气资源的有效勘探和开发。 As an example, if the particle size of the sample is pulverized from 20 mesh to 200 mesh, the SSA/PV value becomes smaller and the correlation coefficient R ^{2 of the} SSA/PV value changes with the pulverized mesh number is above 0.6, indicating the compactness The pore structure test characterization data of the reservoir nano-scale pore structure sample has certain errors that need to be corrected. ^{The correlation coefficient R 2} of the SSA/PV value of different samples with the change of the crushing mesh is also different, indicating that it is also related to the type of sample. Oil and natural gas are mainly stored and seeped in the nano-scale pores and fractures system in tight reservoirs. If the particle size of the tight reservoir sample is crushed from 20 mesh to 200 mesh, the SSA/PV value becomes smaller and the SSA/PV value changes with the crushing mesh. If the correlation coefficient R ^{2 of the} change is above 0.6, the error in the detection of the traditional tight reservoir nano-scale pore structure test characterization data will affect or even mislead the effective and reasonable evaluation and judgment of the pore and fracture system of the tight reservoir, which is not conducive to Effective exploration and development of oil and gas resources.

有益效果Beneficial effect

本方案提供的通过建立氮气吸附量随P/P ₀变化的等温吸附曲线，选择0.05<P/P ₀<0.35范围内的等温吸附曲线，计算出单层吸附需要的氮气体积V _m，再通过BET比表面积公式计算样品的比表面SSA，可得到不同粉碎目数下准确性较高的样品的比表面SSA值。根据NLDFT密度函数理论法，选择微孔、介孔和宏孔的临界P/P ₀值分统计得到微孔、介孔和宏孔的孔体积，进而得到样品中不同类型孔隙的孔体积随粉碎粒径增加的变化情况。最后通过样品不同粉碎粒径下SSA/PV的变化判断纳米级孔隙结构变化。 This solution provides the establishment of a nitrogen adsorption _{isotherm curve that changes with P/P 0} , selects the isotherm adsorption curve in the _{range of 0.05<P/P 0} <0.35, calculates the nitrogen volume V _m required for monolayer adsorption, and then passes The BET specific surface area formula calculates the specific surface SSA of the sample, and the specific surface SSA value of the sample with higher accuracy under different crushing meshes can be obtained. According to the NLDFT density function theory method, the critical P/P ₀ values of micropores, mesopores and macropores are selected for statistical analysis to obtain the pore volume of micropores, mesopores and macropores, and the pore volume of different types of pores in the sample is obtained as a function of the crushed particle size. Increased changes. Finally, the change of nano-scale pore structure was judged by the change of SSA/PV under different crushed particle sizes of the sample.

本方案的判断方法准确检测出不同粉碎粒径下样品的比表面积SSA和总孔体积PV，既可判断制样损伤过程对致密储层样品中纳米级孔隙结构的影响，又可准确判断出传统的致密储层纳米级孔隙定性与定量研究方法中由于制样过程中孔隙结构变化对研究结果产生的误差影响，对密油气资源的勘探和开发具有重要意义。The judgment method of this scheme accurately detects the specific surface area SSA and total pore volume PV of samples under different crushed particle sizes, which can not only judge the influence of sample preparation damage process on the nano-scale pore structure in tight reservoir samples, but also accurately judge the traditional The qualitative and quantitative research methods of nano-scale pores in tight reservoirs are of great significance to the exploration and development of tight oil and gas resources due to the influence of pore structure changes on the research results during the sample preparation process.

附图说明Description of the drawings

图1是本发明实施例中1号样品在不同粉碎目数下的等温吸附曲线图；Figure 1 is a graph showing the adsorption isotherm of sample No. 1 under different crushing meshes in an embodiment of the present invention;

图2是本发明实施例中2号样品在不同粉碎目数下的等温吸附曲线图；Figure 2 is a graph showing the adsorption isotherm of sample No. 2 under different crushing meshes in an embodiment of the present invention;

图3是本发明实施例中3号样品在不同粉碎目数下的等温吸附曲线图；Figure 3 is a graph showing the adsorption isotherm of sample No. 3 under different crushing meshes in an embodiment of the present invention;

图4是本发明实施例中4号样品在不同粉碎目数下的等温吸附曲线图；4 is a graph showing the adsorption isotherm of sample No. 4 under different crushing meshes in an embodiment of the present invention;

图5是本发明实施例中5号样品在不同粉碎目数下的等温吸附曲线图；Fig. 5 is a graph showing the adsorption isotherm of sample No. 5 under different crushing meshes in an embodiment of the present invention;

图6是本发明实施例中6号样品在不同粉碎目数下的等温吸附曲线图；Fig. 6 is a graph showing the adsorption isotherm of sample No. 6 under different crushing meshes in an embodiment of the present invention;

图7是本发明实施例中6个样品在不同粉碎目数下SSA值的变化曲线图；Fig. 7 is a graph showing the change of SSA value of 6 samples under different crushing meshes in the embodiment of the present invention;

图8是本发明实施例中6个样品在不同粉碎目数下SAA的增长率曲线图；Fig. 8 is a graph showing the growth rate of SAA under different crushing meshes for 6 samples in the embodiment of the present invention;

图9是本发明实施例中6个样品在不同粉碎目数下微孔的孔体积变化曲线图；Fig. 9 is a graph showing the change of the pore volume of the micropores under different crushing meshes for 6 samples in the embodiment of the present invention;

图10是本发明实施例中6个样品在不同粉碎目数下介孔的孔体积变化曲线图；Figure 10 is a graph showing the pore volume change curve of mesopores under different crushing meshes for 6 samples in an embodiment of the present invention;

图11是本发明实施例中6个样品在不同粉碎目数下宏孔的孔体积变化曲线图；Figure 11 is a graph showing the pore volume change curve of macropores under different crushing meshes for 6 samples in the embodiment of the present invention;

图12是本发明实施例中6个样品在不同粉碎目数下PV值的变化曲线图；Fig. 12 is a graph showing the variation of PV values of 6 samples under different crushing meshes in the embodiment of the present invention;

图13是本发明实施例中6个样品在不同粉碎目数下PV值的增长率曲线图；Fig. 13 is a graph showing the growth rate of PV value of 6 samples under different crushing meshes in the embodiment of the present invention;

图14是本发明实施例中6个样品在不同粉碎目数下SSA/PV值的变化曲线图。Fig. 14 is a graph showing the change of SSA/PV value of 6 samples under different crushing meshes in the embodiment of the present invention.

本发明的实施方式Embodiments of the present invention

实施例Example

1、设备1. Equipment

低温氮气吸附仪。Low temperature nitrogen adsorption instrument.

2、样品2. Sample

钻井获得的页岩岩心，取6块页岩岩心样品，分别将其粉碎成20目、80目和200目。From the shale core obtained by drilling, six shale core samples were taken and crushed into 20 mesh, 80 mesh and 200 mesh.

3、判断方法3. Judgment method

样品在温度为100℃下，真空脱气9h。通过计算脱气后样品管质量与脱气前空管的质量之差得到经过真空脱气后样品的质量W。将脱气后的样品置于液氮中，测定在预先设定的多个压力点下样品的氮气吸附量，获得样品等温吸附曲线，6块样品在不同粉碎目数下的等温吸附曲线如图1-6所示。The sample was degassed under vacuum for 9h at a temperature of 100°C. The mass W of the sample after vacuum degassing is obtained by calculating the difference between the mass of the sample tube after degassing and the mass of the empty tube before degassing. Place the degassed sample in liquid nitrogen, measure the nitrogen adsorption capacity of the sample at multiple pre-set pressure points, and obtain the sample isotherm adsorption curve. The isotherm adsorption curve of 6 samples under different crushing meshes is shown in the figure Shown in 1-6.

选取0.1≤P/P ₀≤0.3范围内的等温吸附曲线，通过斜率s和截距i求得单层吸附需要的氮气体积V _m，V _m=1/（s+i）；利用BET比表面积公式计算样品的比表面SSA；所述BET比表面积公式为SAA=（V _m×σ）/22400W，式中：σ为被吸附气体的截面积；W为真空脱气后的样品质量；6块样品在不同粉碎目数下的计算得到的比表面SSA值如表1所示，6块样品在不同粉碎目数下SSA值的变化曲线如图7所示。 Select the adsorption isotherm curve in the range of 0.1≤P/P _{0 ≤0.3, calculate the nitrogen volume V m} required for monolayer adsorption through the slope s and intercept i, V _m =1/(s+i); use the BET specific surface area The formula calculates the specific surface SSA of the sample; the BET specific surface area formula is SAA=(V _m ×σ)/22400W, where: σ is the cross-sectional area of the adsorbed gas; W is the mass of the sample after vacuum degassing; 6 pieces The calculated specific surface SSA values of the samples under different crushing meshes are shown in Table 1, and the change curves of the SSA values of 6 samples at different crushing meshes are shown in Figure 7.

表1 6块样品不同粉碎目数下的SSA值Table 1 SSA values of 6 samples under different crushing meshes

样品编号 Sample serial number	SSA值（m2/g） 20目 SSA value (m2/g) 20 mesh	SSA值（m2/g） 80目 SSA value (m2/g) 80 mesh	SSA值（m2/g） 200目 SSA value (m2/g) 200 mesh
1 1	6.897 6.897	6.778 6.778	6.471 6.471
2 2	8.168 8.168	7.223 7.223	6.748 6.748
3 3	4.414 4.414	7.384 7.384	7.212 7.212
4 4	8.18 8.18	9.993 9.993	6.185 6.185
5 5	2.703 2.703	2.186 2.186	2.387 2.387
6 6	4.09 4.09	4.99 4.99	4.413 4.413

根据表1中样品不同粉碎目数下的SSA值计算出6块样品随粉碎目数的增加SAA的增量和增长率，计算结果如表2所示，SAA的增长率曲线如图8所示。According to the SSA values of the samples in Table 1 under different crushing meshes, the increment and growth rate of SAA of 6 samples with the increase of crushing meshes are calculated. The calculation results are shown in Table 2, and the growth rate curve of SAA is shown in Figure 8. .

表2 SAA的增量和增长率Table 2 Increment and growth rate of SAA

样品序号 Sample number	20-80目SAA的增量 20-80 mesh SAA increment	80-200目SAA的增量 80-200 mesh SAA increment	20-80目SAA的增长率 20-80 mesh SAA growth rate	80-200目SAA的增长率 80-200 mesh SAA growth rate
1 1	-0.119 -0.119	-0.307 -0.307	-1.73% -1.73%	-4.53% -4.53%
2 2	-0.945 -0.945	-0.475 -0.475	-11.57 -11.57	-6.58% -6.58%
3 3	2.790 2.790	-0.172 -0.172	67.29% 67.29%	-2.33% -2.33%
4 4	1.813 1.813	-3.808 -3.808	22.16% 22.16%	-38.11% -38.11%
5 5	-0.517 -0.517	0.201 0.201	-19.13% -19.13%	9.19% 9.19%
6 6	0.900 0.900	-0.577 -0.577	22.00% 22.00%	-11.56% -11.56%

选取0.01≤P/P ₀≤0.995范围内的数值，根据NLDFT密度函数理论法，通过ASiQ软件统计得出样品中微孔、介孔和宏孔的孔体积，进而得到样品中微孔、介孔和宏孔的总孔体积PV，6块样品在不同粉碎目数下的计算得到的微孔、介孔和宏孔的孔体积以及总孔体积PV值，计算得到的微孔、介孔和宏孔的孔体积值如表3所示，微孔的孔体积变化曲线如图9所示，介孔的孔体积变化曲线如图10所示，宏孔的孔体积变化曲线如图11所示，计算得到的总孔体积PV值如表4所示，PV值的变化曲线如图12所示。 Select the value in the range of 0.01≤P/P ₀ ≤0.995, according to the NLDFT density function theory method, the pore volume of the micropores, mesopores and macropores in the sample is obtained through statistics by ASiQ software, and then the micropores, mesopores and macropores in the sample are obtained. The total pore volume PV of the pores, the calculated pore volume of micropores, mesopores and macropores and the total pore volume PV value of 6 samples under different crushing meshes, and the calculated pore volume of micropores, mesopores and macropores The values are shown in Table 3. The pore volume change curve of micropores is shown in Fig. 9, the pore volume change curve of mesopores is shown in Fig. 10, and the pore volume change curve of macropores is shown in Fig. 11. The calculated total The pore volume PV value is shown in Table 4, and the variation curve of the PV value is shown in Fig. 12.

表3 微孔、介孔和宏孔的孔体积Table 3 Pore volume of micropores, mesopores and macropores

样品序号 Sample number	粉碎目数 Smashing mesh	微孔孔隙体积cc/g Micropore pore volume cc/g	介孔孔隙体积cc/g Mesoporous pore volume cc/g	宏孔孔隙体积cc/g Macro pore volume cc/g
1 1	20 20	0.00261 0.00261	0.012181 0.012181	0.003309 0.003309
1 1	80 80	0.002831 0.002831	0.013422 0.013422	0.010147 0.010147
1 1	200 200	0.002505 0.002505	0.01237 0.01237	0.006675 0.006675
2 2	20 20	0.003489 0.003489	0.011512 0.011512	0.003069 0.003069
2 2	80 80	0.002907 0.002907	0.014975 0.014975	0.012348 0.012348
2 2	200 200	0.002646 0.002646	0.016932 0.016932	0.016272 0.016272
3 3	20 20	0.001684 0.001684	0.003281 0.003281	0.002929 0.002929
3 3	80 80	0.002899 0.002899	0.011326 0.011326	0.014595 0.014595
3 3	200 200	0.002899 0.002899	0.015749 0.015749	0.013612 0.013612
4 4	20 20	0.003625 0.003625	0.0047156 0.0047156	0.0029594 0.0029594
4 4	80 80	0.003898 0.003898	0.012406 0.012406	0.022646 0.022646
4 4	200 200	0.0025 0.0025	0.019966 0.019966	0.022064 0.022064
5 5	20 20	0.0007351 0.0007351	0.0032649 0.0032649	0.000752 0.000752
5 5	80 80	0.0007948 0.0007948	0.0052052 0.0052052	0.00671 0.00671
5 5	200 200	0.0008545 0.0008545	0.0054411 0.0054411	0.0066644 0.0066644
6 6	20 20	0.001542 0.001542	0.0054033 0.0054033	0.0017597 0.0017597
6 6	80 80	0.001916 0.001916	0.010672 0.010672	0.013082 0.013082
6 6	200 200	0.001712 0.001712	0.012501 0.012501	0.017957 0.017957

表4 6块样品不同粉碎目数下的总孔体积PV值Table 4 PV value of total pore volume under different crushing meshes of 6 samples

样品编号 Sample serial number	PV值（cc/g） 20目 PV value (cc/g) 20 mesh	PV值（cc/g） 80目 PV value (cc/g) 80 mesh	PV值（cc/g） 200目 PV value (cc/g) 200 mesh
1 1	0.018100 0.018100	0.026400 0.026400	0.02155 0.02155
2 2	0.018070 0.018070	0.030230 0.030230	0.03585 0.03585
3 3	0.007894 0.007894	0.028820 0.028820	0.03226 0.03226
4 4	0.011300 0.011300	0.038950 0.038950	0.04453 0.04453
5 5	0.004752 0.004752	0.012710 0.012710	0.01296 0.01296
6 6	0.008705 0.008705	0.025670 0.025670	0.03217 0.03217

根据表3中样品不同粉碎目数下的总孔体积PV值计算出6块样品随粉碎目数的增加PV的增量和增长率，计算结果如表5所示，绘制出6块样品随粉碎目数的增加PV的增长率曲线如图13所示。According to the PV value of the total pore volume under different crushing meshes of the samples in Table 3, calculate the PV increment and growth rate of 6 samples with the increase of crushing meshes. The calculation results are shown in Table 5. The growth rate curve of PV with increasing mesh is shown in Figure 13.

表5 PV的增量和增长率Table 5 Increment and growth rate of PV

样品序号 Sample number	20-80目PV的增量 20-80 mesh PV increment	80-200目PV的增量 80-200 mesh PV increment	20-80目PV的增长率 20-80 mesh PV growth rate	80-200目PV的增长率 80-200 mesh PV growth rate
1 1	0.008300 0.008300	-0.004850 -0.004850	45.86% 45.86%	-18.37% -18.37%
2 2	0.012160 0.012160	0.005620 0.005620	67.29% 67.29%	18.59% 18.59%
3 3	0.020926 0.020926	0.003440 0.003440	265.09% 265.09%	11.94% 11.94%
4 4	0.027650 0.027650	0.005580 0.005580	244.69% 244.69%	14.33% 14.33%
5 5	0.007958 0.007958	0.000250 0.000250	167.47% 167.47%	1.97% 1.97%
6 6	0.016965 0.016965	0.006500 0.006500	194.89% 194.89%	25.32% 25.32%

由表1-2和表4-5中的数据以及图7-8和图12-13可知，随着样品粉碎目数由20目增加到80目再到200目，岩石样品孔缝***中，SSA与PV的变化情况如下：From the data in Table 1-2 and Table 4-5, as well as Figure 7-8 and Figure 12-13, as the number of crushed samples increases from 20 meshes to 80 meshes and then to 200 meshes, in the rock sample pore and fracture system, The changes of SSA and PV are as follows:

1）SSA变化不大，PV增加较大。即在实验条件下，将页岩样品由20目粉碎至80目再到200目的过程中，对岩石样品中微孔的改变较少，因此，微孔级别孔隙的含量变化幅度不大。在制样过程中，反而随着粉碎目数的增加，增加了样品中介孔和宏孔的数量。宏孔数量增加的原因可以为两类：a、介孔受到破坏，孔隙被连通成为宏孔；b、产生了新的微裂缝，连通了先前封闭的孔隙。1) SSA has not changed much, but PV has increased greatly. That is, under the experimental conditions, the process of crushing the shale sample from 20 mesh to 80 mesh and then to 200 mesh has little change in the micropores in the rock sample. Therefore, the content of micropore-level pores does not change much. In the sample preparation process, as the number of crushing meshes increases, the number of mesopores and macropores in the sample increases. There are two reasons for the increase in the number of macropores: a. The mesopores are destroyed and the pores are connected to become macropores; b. New microcracks are generated, which connect the previously closed pores.

2）从80目到200目的粉碎过程中，PV的增长率相比于20目到80目的变化过程较小。即在20目到80目这个粉碎过程对页岩样品的破坏大幅增加了孔缝***中的连通孔隙，使得PV值增长幅度较大。而从80目到200目这个对页岩样品的破环过程，新增加的连通孔隙较少，且微孔的变化不大，即20目到80目这个粉碎过程页岩样品的孔隙结构基本上被破坏，继续粉碎已无法产生更多的新孔缝。2) In the process of crushing from 80 mesh to 200 mesh, the growth rate of PV is smaller than that of 20 mesh to 80 mesh. That is, the destruction of shale samples during the crushing process from 20 mesh to 80 mesh greatly increases the connected pores in the pore and fracture system, which makes the PV value increase greatly. In the process of breaking the shale sample from 80 mesh to 200 mesh, there are fewer newly added connected pores and little change in micropores. That is, the pore structure of the shale sample during the crushing process from 20 mesh to 80 mesh is basically If it is destroyed, it can no longer produce more new holes and cracks if it continues to be crushed.

因此，在样品粉碎制样过程中随着粉碎目数的增加，页岩样品中会产生了新的连通孔隙，这些连通孔隙通过增加的微裂缝开启，但这种增大的趋势并不是一直进行的，当粉碎粒径达到某一特定值时，样品的孔隙体积增长幅度减小，即此时，页岩样品的微观孔隙结构基本被破坏导致无法产生更多的新孔缝。Therefore, in the process of sample crushing and sample preparation, as the number of crushing meshes increases, new connected pores will be generated in the shale sample. These connected pores are opened through the increased micro-cracks, but this increasing trend is not always going on. Yes, when the crushed particle size reaches a certain value, the pore volume growth rate of the sample decreases, that is, at this time, the microscopic pore structure of the shale sample is basically destroyed and no more new pores and fractures can be produced.

3）对SSA/PV数据进行统计分析，结果如表6所示。3) Perform statistical analysis on SSA/PV data, and the results are shown in Table 6.

表6 样品由20目到80目再到200目SSA/PV值及变化率Table 6 SSA/PV value and rate of change of samples from 20 mesh to 80 mesh to 200 mesh

样品序号 Sample number	20目SSA/PV 20 mesh SSA/PV	80目SSA/PV 80 mesh SSA/PV	200目SSA/PV 200 mesh SSA/PV	20-80目SSA/PV增长率 20-80 mesh SSA/PV growth rate	80-200目SSA/PV增长率 80-200 mesh SSA/PV growth rate
6 6	381.0497 381.0497	256.7424 256.7424	300.2784 300.2784	-32.6223% -32.6223%	16.9571% 16.9571%
13 13	452.0199 452.0199	238.9348 238.9348	188.2287 188.2287	-47.1406% -47.1406%	-21.2217% -21.2217%
25 25	559.1589 559.1589	256.2110 256.2110	223.5586 223.5586	-54.1792% -54.1792%	-12.7443% -12.7443%
44 44	723.8938 723.8938	256.5597 256.5597	138.8951 138.8951	-64.5584% -64.5584%	-45.8625% -45.8625%
46 46	568.8131 568.8131	171.9906 171.9906	184.1821 184.1821	-69.7633% -69.7633%	7.0885% 7.0885%
52 52	469.8449 469.8449	194.3903 194.3903	137.1775 137.1775	-58.6267% -58.6267%	-29.4319% -29.4319%

根据表6中的数据绘制出6块样品的SSA/PV在80目到200目之间的变化曲线，SSA/PV的变化曲线如图14所示。According to the data in Table 6, draw the change curve of SSA/PV of 6 samples between 80 mesh and 200 mesh. The change curve of SSA/PV is shown in Figure 14.

由表6和图14可知，样品粉碎目数由20目增加到80目再到200目的过程中，SSA/PV值与粉碎目数具有一定的相关性（R ²变化范围在0.6-0.8），SSA/PV随粉碎目数一直保持减小的趋势。说明制样过程随着粉碎目数的增加，增加了孔隙***内部的连通孔隙，产生了新的孔缝，使得孔隙体积增加，对页岩岩心的纳米级孔隙结构产生了损伤。通过对比不同类型样品的SSA/PV值的变化率，可说明制样损伤程度使传统孔隙结构试验表征数据产生较大误差，影响油气勘探结果，需要对相关表征数据进行矫正。 It can be seen from Table 6 and Figure 14 that the SSA/PV value has a certain correlation with the crushing mesh (R ² varies in the range of 0.6-0.8) in the process of increasing the sample size from 20 mesh to 80 mesh and then to 200 mesh. SSA/PV keeps decreasing with the crushing mesh. It shows that as the number of crushing meshes increases during the sample preparation process, the interconnected pores in the pore system are increased, and new pores and fractures are created, which increases the pore volume and damages the nano-scale pore structure of the shale core. By comparing the rate of change of the SSA/PV values of different types of samples, it can be shown that the degree of sample preparation damage causes large errors in the characterization data of traditional pore structure tests, which affects the results of oil and gas exploration, and the relevant characterization data needs to be corrected.

上述检测结果进一步验证了用SSA/PV随目数的变化情况作为判断制样过程中致密储层微观孔隙结构变化以及判断致密储层纳米级孔隙结构样品的孔隙结构试验表征数据准确度的可行性。The above test results further verify the feasibility of using the change of SSA/PV with the number of meshes to determine the microscopic pore structure changes of tight reservoirs during the sample preparation process and to determine the accuracy of the pore structure test characterization data of tight reservoir nano-scale pore structure samples. .

以上所述仅为本方案的较佳实施例而已，并不用以限制本方案，凡在本方案的精神和原则之内所作的任何修改、等同替换或改进等，均应包含在本方案的保护范围之内。The above descriptions are only preferred embodiments of this solution, and are not intended to limit this solution. Any modification, equivalent replacement or improvement made within the spirit and principle of this solution shall be included in the protection of this solution. Within range.

Claims (10)

1. 一种纳米级孔隙结构变化的判断方法，包括如下步骤：A method for judging nano-scale pore structure changes, including the following steps:

   a、将真空脱气后的纳米级孔隙结构样品置于液氮中，在预先设定的多个压力值P下检测所述样品的氮气吸附量，获得所述样品的氮气吸附量随相对压力P/P ₀变化的等温吸附曲线，所述P ₀为吸附温度下氮气的饱和蒸气压； a. Put the sample of the nano-scale pore structure after vacuum degassing in liquid nitrogen, and detect the nitrogen adsorption capacity of the sample under a plurality of preset pressure values P, and obtain the nitrogen adsorption capacity of the sample as the relative pressure An adsorption isotherm curve of P/P _{0 change, where P 0} is the saturated vapor pressure of nitrogen at the adsorption temperature;

   b、选取0.05≤P/P ₀≤0.35范围内的等温吸附曲线，通过斜率s和截距i求得单层吸附需要的氮气体积V _m；利用BET比表面积公式计算样品的比表面SSA；所述BET比表面积公式为SAA=（V _m×σ）/22400W，式中：σ为被吸附气体的截面积；W为真空脱气后的样品质量； b. Select the _{adsorption isotherm curve in the range of 0.05≤P/P 0 ≤0.35, and obtain the nitrogen volume V m} required for monolayer adsorption through the slope s and intercept i; use the BET specific surface area formula to calculate the specific surface SSA of the sample; The BET specific surface area formula is SAA=(V _m ×σ)/22400W, where: σ is the cross-sectional area of the adsorbed gas; W is the mass of the sample after vacuum degassing;

   c、根据NLDFT密度函数理论法，分别计算出微孔、介孔和宏孔的孔体积，进而得到样品中所述微孔、介孔和宏孔的孔体积之和PV；c. According to the NLDFT density function theory method, calculate the pore volume of micropores, mesopores and macropores respectively, and then obtain the sum of the pore volume PV of the micropores, mesopores and macropores in the sample;

   d、计算样品不同粉碎粒径下SSA/PV的值，根据所述SSA/PV的值随粉碎目数增加的变化趋势判断粉碎过程对样品中纳米级孔隙结构变化的影响。d. Calculate the value of SSA/PV under different crushed particle sizes of the sample, and judge the influence of the crushing process on the change of the nano-scale pore structure in the sample according to the change trend of the value of the SSA/PV with the increase of crushing mesh.
2. 根据权利要求1所述的判断方法，其特征在于，步骤a中所述的真空脱气的温度为90-120℃。The judging method according to claim 1, wherein the temperature of the vacuum degassing in step a is 90-120°C.
3. 根据权利要求1所述的判断方法，其特征在于，步骤a中所述的真空脱气的时间≥9h。The judging method according to claim 1, wherein the vacuum degassing time in step a is greater than or equal to 9h.
4. 根据权利要求1所述的判断方法，其特征在于，步骤b中选取0.1≤P/P ₀≤0.3范围内的等温吸附曲线，通过斜率s和截距i求得单层吸附需要的氮气体积V _m。 The judgment method according to claim 1, characterized in that, in step b, _{an isotherm adsorption curve in the range of 0.1≤P/P 0} ≤0.3 is selected, and the nitrogen volume V required for monolayer adsorption is obtained by the slope s and intercept i _m .
5. 根据权利要求1所述的判断方法，其特征在于，步骤b中所述V _m与所述斜率s和所述截距i的关系为：V _m=1/（s+i）。 The judgment method according to claim 1, wherein the _{relationship between the V m} and the slope s and the intercept i in _{step b is: V m} =1/(s+i).
6. 根据权利要求1所述的判断方法，其特征在于，步骤c中选取0.01≤P/P ₀≤0.995范围内的数值，根据NLDFT密度函数理论法，通过ASiQ软件统计得到所述微孔、介孔和宏孔的孔体积。 The judgment method according to claim 1, characterized in that, in step c, _{a value in the range of 0.01≤P/P 0} ≤0.995 is selected, and the micropores and mesopores are obtained by statistics of the ASiQ software according to the NLDFT density function theory method. And the pore volume of the macropore.
7. 根据权利要求1所述的判断方法，其特征在于，步骤d中根据样品粉碎粒径由20目到200目时SSA/PV值的变化来判断所述样品中纳米级孔隙结构的变化。The judging method according to claim 1, wherein in step d, the change of the nano-scale pore structure in the sample is judged according to the change of the SSA/PV value when the particle size of the sample is crushed from 20 mesh to 200 mesh.
8. 权利要求1-7任一项所述的判断方法用于判断制样损伤过程对致密储层纳米级孔隙结构影响的应用。The judgment method of any one of claims 1-7 is used to judge the influence of the sample preparation damage process on the nano-scale pore structure of the tight reservoir.
9. 权利要求1-7任一项所述的判断方法用于判断致密储层纳米级孔隙结构样品的孔隙结构试验表征数据准确度中的应用。The judgment method according to any one of claims 1-7 is used to judge the accuracy of the pore structure test characterization data of the nano-scale pore structure sample of the tight reservoir.
10. 根据权利要求9所述的应用，其特征在于：若样品粉碎粒径由20目到200目时，SSA/PV值变小且SSA/PV值随粉碎目数变化的相关性系数R ²在0.6以上，则说明所述致密储层纳米级孔隙结构样品的所述孔隙结构试验表征数据存在误差且需要矫正。 The application according to claim 9, characterized in that: if the particle size of the sample is crushed from 20 mesh to 200 mesh, the SSA/PV value becomes smaller and the correlation coefficient R ^{2 of the} SSA/PV value changes with the crushed mesh is 0.6 The above indicates that the pore structure test characterization data of the nano-scale pore structure sample of the tight reservoir has errors and needs to be corrected.