CN111751188A - Macroscopic fracture mechanical analysis method for large-mixing-amount rubber concrete - Google Patents

Abstract

The invention discloses a macroscopic fracture mechanics analysis method for large-doped rubber concrete, which comprises the following steps: preparing a test piece, pretreating the test piece, scanning a test piece slice, simulating a microscopic structure of the test piece, and analyzing and comparing a real test and a simulation test; according to the invention, the cubic test pieces with different rubber doping amounts are prepared through reasonable raw material proportion, the test pieces are pretreated to be conveniently scanned by a full-automatic panoramic fluorescence microscope, so that the porosity of concrete is conveniently observed, the influence of the rubber doping amount on the mechanical property of the rubber concrete is analyzed based on a microstructure, the microstructure of the test pieces is simulated according to scanning images of sample slices to generate a microstructure model of the rubber concrete, and then a real test of the test pieces is analyzed and compared with a simulation test of the microstructure model of time, so that the influence of the rubber doping amount on the macroscopic fracture performance of the rubber concrete is analyzed based on the microstructure, and the method has better applicability and accuracy.

Description

Macroscopic fracture mechanical analysis method for large-mixing-amount rubber concrete

Technical Field

The invention relates to the technical field of material performance analysis, in particular to a microscopic fracture mechanics analysis method for large-doped rubber concrete.

Background

The rubber concrete is prepared by mixing, molding and curing rubber emulsion, auxiliary additives and cement when cement mortar or concrete is prepared, has excellent impact resistance and wear resistance, and can better solve the problem of recycling waste rubber products at the same time;

in order to promote the popularization and application of the large-doped rubber concrete in actual engineering such as water conservancy, civil engineering, traffic and the like, the fracture performance of the rubber concrete needs to be analyzed to reveal the fracture performance mechanism of the rubber concrete and prolong the service life of a rubber concrete structure, but the analysis on the fracture process mechanism of the large-doped rubber concrete is less at present, the analysis result is mostly not representative, and the macroscopic performance of the material performance is often indistinguishable from the microscopic mechanics, and the microscopic numerical simulation can effectively reflect the deformation and the cracking state of the structure under the load action, so the invention provides the microscopic fracture mechanics analysis method of the large-doped rubber concrete to solve the problems in the prior art.

Disclosure of Invention

Aiming at the problems, the invention aims to provide a microscopic fracture mechanics analysis method for large-doped rubber concrete, the method comprises the steps of firstly, regarding the rubber concrete as a multiphase composite material consisting of rubber, coarse aggregate, a mortar matrix, a rubber-mortar interface transition area, a coarse aggregate-mortar interface transition area and interface initial defects, and then, establishing a two-dimensional rubber concrete microscopic structure based on a real microscopic structure of a rubber concrete interface so as to represent the influence of the rubber doping on the macroscopic fracture performance of the rubber concrete through the microscopic structure, so that the analysis method has better applicability and accuracy.

In order to achieve the purpose of the invention, the invention is realized by the following technical scheme: a mechanical analysis method for microscopic fracture of large-doped rubber concrete comprises the following steps:

the method comprises the following steps: preparation of test pieces

Putting portland cement, fine aggregate, coarse aggregate, rubber particles and water into a stirrer according to a specified proportion for stirring and mixing, pouring and molding after uniform mixing to obtain rubber concrete cubic test pieces with length, width and height of 100 multiplied by 100mm and different rubber particle mixing amounts, and then putting the poured rubber concrete cubic test pieces with different rubber particle mixing amounts into a standard curing chamber for curing, wherein the curing age is 28 days;

step two: pretreatment of test pieces

According to the first step, taking out a cubic test piece which is reached in the maintenance age, cutting a test piece slice with the length, width and height of 100 multiplied by 15mm, polishing the observation surface of the test piece slice by using an automatic polishing machine, cleaning the polished test piece slice, wiping the surface water stain after the cleaning is finished, putting the wiped test piece slice into a vacuum drying box for fully drying, putting the dried test piece slice into a vacuum impregnation box for vacuumizing, filling epoxy resin doped with fluorescent powder for finishing impregnation, taking out the test piece slice after the impregnation is finished, coating a layer of epoxy resin on the observation surface of the test piece slice, standing for 35 minutes, scraping the residual epoxy resin on the surface, and performing secondary polishing on the test piece slice;

step three: specimen slice scanning

According to the second step, firstly, scanning panoramic microscopic images of sample slices with different rubber mixing amounts after secondary polishing through a full-automatic panoramic fluorescence microscope, obtaining the panoramic microscopic images of observation surfaces of the sample slices, and observing the porosity of the sample slices with different mixing amounts through the obtained panoramic microscopic images to obtain the influence of the mixing amount of the rubber particles on the mechanical property of the rubber concrete;

step four: test piece mesoscopic structure simulation

According to the third step, firstly, according to the panoramic microscopic image, the coarse aggregate and the rubber are put on a two-dimensional plane through Matlab software, the coarse aggregate is simplified into a polygon based on a real structure, the rubber is simplified into a circle for model building, then according to the distribution rule of the coarse aggregate and the rubber, a particle flow analysis program is compiled based on the Matlab software by means of a Monte Carlo method to generate a two-dimensional rubber concrete rubber and coarse aggregate structure model, the generated rubber and coarse aggregate particles are further subjected to position information and then are expanded to a certain width, then a program is compiled to generate a rubber-mortar interface and a coarse aggregate-mortar interface, after operation, the center coordinates and the radius of the rubber and rubber-mortar interface, the multipoint position coordinates of the coarse aggregate and coarse aggregate-mortar interface are obtained, then a language is parameterized and designed based on ANSYS software after the position coordinates of each phase of materials are obtained, and the mortar matrix and the, Establishing a coarse aggregate, a rubber-mortar interface transition area and a coarse aggregate-mortar interface transition area, and finally generating a rubber concrete mesoscopic structure model;

step five: analysis and comparison of real test and simulation experiment

According to the fourth step, firstly, a universal testing machine is adopted to carry out real fracture resistance tests on cubic test pieces with different rubber mixing amounts and record the test results, then the rubber concrete mesoscopic structure model is subjected to simulated fracture resistance tests according to the real tests and the test conclusions are stored, and then the real test results and the simulated test conclusions are compared and analyzed to obtain the relation between mesoscopic mechanics and macroscopic expressions of the rubber concrete fracture properties with different mixing amounts.

The further improvement lies in that: in the first step, the coarse aggregate is formed by mixing small limestone stones with the particle size of 5-10mm and large limestone stones with the particle size of 10-20mm in a ratio of 3:7, the rubber particles are rubber particles with the particle size of 3-6mm obtained by cutting waste tires, and the fine aggregate is natural river sand.

The further improvement lies in that: in the second step, in the polishing process of the sample slice, firstly polishing for 20 minutes by using the abrasive with the specification of 300#, then polishing for 10 minutes by using the abrasive with the specification of 800#, and finally polishing for 5 minutes by using the abrasive with the specification of 1000#, wherein the rotating speed of the automatic polishing machine is set to be 50r/min in the polishing process.

The further improvement lies in that: and in the second step, the vacuum degree in the vacuum drying oven is kept above 0.9, the temperature of the vacuum drying oven is set to be 40 ℃, sample slices are taken out every 6 hours in the drying process and weighed, and when the mass loss of the sample slices in 24 hours is less than 0.1g, the drying is finished.

The further improvement lies in that: in the third step, when the sample slice is scanned, the observation area of the selected sample slice is within the range of 90mm multiplied by 90mm, meanwhile, the observation area is equally divided into nine equal parts for observation, and the image obtained by scanning is formed by splicing nine sub-images of which the pixels are 12664 multiplied by 12664.

The further improvement lies in that: in the fourth step, a two-dimensional conversion formula which is derived by a Walraven J.C probability statistics-based method and accords with a three-dimensional Fuller grading curve is adopted to ensure the convenience of numerical simulation of the two-dimensional rubber concrete, and the formula is

In the formula P_cThe diameter d of any point on the cross section of the rubber concrete is less than d₀Probability of (P)_KThe volume of the particles is the percentage of the total volume of the rubber concrete, d is the actually required particle diameter of the particles, d₀For a defined particle size, d_maxThe largest particle size.

The invention has the beneficial effects that: according to the invention, a rubber concrete cubic test piece with different rubber mixing amounts is prepared through reasonable raw material proportion, then the test piece is cut, polished, cleaned, dried, vacuum dipped and polished for the second time to enable the test piece slices to be conveniently scanned and observed by a full-automatic panoramic fluorescence microscope, so that the porosity of concrete can be conveniently observed, the influence of the mixing amount of rubber on the mechanical property of the rubber concrete is analyzed based on a microstructure, then the microstructure of the test piece is simulated according to the scanned image of the test piece to generate a microstructure model of the rubber concrete, then the real test of the test piece is analyzed and compared with the simulation test of the microstructure model of time, so that the influence of the mixing amount of the rubber on the macroscopic fracture property of the rubber concrete is analyzed based on the microstructure, and the method is characterized in that the rubber concrete is regarded as a rubber concrete with different rubber, coarse aggregate, The method is characterized in that a multiphase composite material consisting of a mortar matrix, a rubber-mortar interface transition area, a coarse aggregate-mortar interface transition area and an interface initial defect is used for establishing a two-dimensional rubber concrete microstructure based on a real microstructure of a rubber concrete interface, so that the influence of rubber mixing amount on the macroscopic fracture performance of the rubber concrete is represented through the microstructure, and the analysis method has good applicability and accuracy.

Drawings

FIG. 1 is a flow chart of the steps of the present invention.

Detailed Description

In order to further understand the present invention, the following detailed description will be made with reference to the following examples, which are only used for explaining the present invention and are not to be construed as limiting the scope of the present invention.

According to the illustration in fig. 1, the embodiment provides a mechanical analysis method for microscopic fracture of large-content rubber concrete, which includes the following steps:

the method comprises the following steps: preparation of test pieces

Mixing fine aggregate consisting of portland cement and natural river sand, limestone small stones with the particle size of 5-10mm and limestone large stones with the particle size of 10-20mm in a ratio of 3:7 to form coarse aggregate, rubber particles with the particle size of 3-6mm and water, which are obtained by cutting waste tires, according to a specified ratio, putting the coarse aggregate and the water into a mixer for mixing, pouring and molding after uniform mixing to obtain rubber concrete cube test pieces with the length, width and height of 100 x 100mm and different rubber particle mixing amounts, and then putting the rubber concrete cube test pieces with different rubber particle mixing amounts obtained by pouring into a standard curing chamber for curing, wherein the curing age is 28 days;

step two: pretreatment of test pieces

According to the first step, a cube test piece which is reached in the maintenance age is taken out and cut into test piece slices with the length, width and height of 100 multiplied by 15mm, an automatic grinding and polishing machine is adopted to polish the observation surface of the test piece slices, grinding materials with the specification of 300# are firstly adopted to polish for 20 minutes in the polishing process, grinding materials with the specification of 800# are adopted to polish for 10 minutes, grinding materials with the specification of 1000# are finally adopted to polish for 5 minutes, the rotating speed of the automatic grinding and polishing machine is set to be 50r/min in the polishing process, the polished test piece slices are cleaned, the surface water stain is wiped after the cleaning is finished, the wiped test piece slices are placed into a vacuum drying box to be fully dried, the vacuum degree in the vacuum drying box is kept to be more than 0.9 in the drying process, the temperature is set to be 40 ℃, the test piece slices are taken out every 6 hours in the drying process to be weighed, and the drying is finished when the mass loss of the test piece slices is less, then placing the dried sample slice into a vacuum impregnation box for vacuumizing and filling epoxy resin doped with fluorescent powder to complete impregnation, taking out the sample slice after the impregnation is completed, coating a layer of epoxy resin on the observation surface of the sample slice, standing for 35 minutes, scraping the residual epoxy resin on the surface, and polishing the sample slice for the second time;

step three: specimen slice scanning

According to the second step, firstly, scanning panoramic microscopic images of sample slices which are polished for the second time and have different rubber mixing amounts through a full-automatic panoramic fluorescence microscope, and acquiring the panoramic microscopic images of observation surfaces of the sample slices, wherein when the sample slices are scanned, the observation areas of the selected sample slices are within a range of 90mm multiplied by 90mm, and meanwhile, the observation areas are equally divided into nine equal parts for observation, the scanned images are formed by splicing nine sub-images of which the pixels are 12664 multiplied by 12664, and then, the porosity of the sample slices with different mixing amounts is observed through the acquired panoramic microscopic images, so that the influence of the mixing amount of rubber particles on the mechanical property of the rubber concrete is obtained;

step four: test piece mesoscopic structure simulation

According to the third step, firstly, according to the panoramic microscopic image, the coarse aggregate and the rubber are put on a two-dimensional plane through Matlab software, the coarse aggregate is simplified into a polygon based on a real structure, the rubber is simplified into a circle for model building, then according to the distribution rule of the coarse aggregate and the rubber, a particle flow analysis program is compiled based on the Matlab software by means of a Monte Carlo method to generate a two-dimensional rubber concrete rubber and coarse aggregate structure model, the generated rubber and coarse aggregate particles are further subjected to position information and then are expanded to a certain width, then a program is compiled to generate a rubber-mortar interface and a coarse aggregate-mortar interface, after operation, the center coordinates and the radius of the rubber and rubber-mortar interface, the multipoint position coordinates of the coarse aggregate and coarse aggregate-mortar interface are obtained, then a language is parameterized and designed based on ANSYS software after the position coordinates of each phase of materials are obtained, and the mortar matrix and the, Establishing a coarse aggregate, a rubber-mortar interface transition area and a coarse aggregate-mortar interface transition area, and finally generating a rubber concrete mesoscopic structure model, wherein in the model simulation process, in order to ensure the convenience of numerical simulation of two-dimensional rubber concrete, a two-dimensional conversion formula which is derived by a Walraven J.C probability statistics-based method and accords with a three-dimensional Fuller grading curve is adopted, and the formula is a two-dimensional conversion formula

In the formula P_cThe diameter d of any point on the cross section of the rubber concrete is less than d₀Probability of (P)_KThe volume of the particles is the percentage of the total volume of the rubber concrete, d is the actually required particle diameter of the particles, d₀For a defined particle size, d_maxThe largest particle size;

step five: analysis and comparison of real test and simulation experiment

According to the fourth step, firstly, a universal testing machine is adopted to carry out real fracture resistance tests on cubic test pieces with different rubber mixing amounts and record the test results, then the rubber concrete mesoscopic structure model is subjected to simulated fracture resistance tests according to the real tests and the test conclusions are stored, and then the real test results and the simulated test conclusions are compared and analyzed to obtain the relation between mesoscopic mechanics and macroscopic expressions of the rubber concrete fracture properties with different mixing amounts.

According to the microscopic fracture mechanical analysis method for the large-doping-amount rubber concrete, cubic rubber concrete test pieces with different rubber doping amounts are prepared through reasonable raw material proportion, then the test pieces are cut, polished, cleaned, dried, vacuum-dipped and polished for the second time, sample slices are conveniently scanned and observed by a full-automatic panoramic fluorescence microscope, so that the porosity of the concrete is conveniently observed, the influence of the rubber doping amount on the mechanical property of the rubber concrete is analyzed based on a microstructure, then the microscopic structure of the test pieces is simulated according to the scanning images of the sample slices, a rubber concrete microscopic structure model is generated, then the real test of the test pieces is analyzed and compared with the simulation test of the microscopic structure model of time, the influence of the rubber doping amount on the macroscopic fracture property of the rubber concrete is analyzed based on the microscopic structure, and the rubber concrete is regarded as the rubber concrete, The method is characterized in that a multiphase composite material consisting of coarse aggregate, a mortar matrix, a rubber-mortar interface transition area, a coarse aggregate-mortar interface transition area and interface initial defects is established on the basis of a real microstructure of a rubber concrete interface, so that the influence of rubber mixing amount on the macroscopic fracture performance of the rubber concrete is represented through a microscopic structure, and the analysis method has good applicability and accuracy.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (6)

1. A method for analyzing the microscopic fracture mechanics of large-doped rubber concrete is characterized by comprising the following steps: the method comprises the following steps:

the method comprises the following steps: preparation of test pieces

Putting portland cement, fine aggregate, coarse aggregate, rubber particles and water into a stirrer according to a specified proportion for stirring and mixing, pouring and molding after uniform mixing to obtain rubber concrete cubic test pieces with length, width and height of 100 multiplied by 100mm and different rubber particle mixing amounts, and then putting the poured rubber concrete cubic test pieces with different rubber particle mixing amounts into a standard curing chamber for curing, wherein the curing age is 28 days;

step two: pretreatment of test pieces

According to the first step, taking out a cubic test piece which is reached in the maintenance age, cutting a test piece slice with the length, width and height of 100 multiplied by 15mm, polishing the observation surface of the test piece slice by using an automatic polishing machine, cleaning the polished test piece slice, wiping the surface water stain after the cleaning is finished, putting the wiped test piece slice into a vacuum drying box for fully drying, putting the dried test piece slice into a vacuum impregnation box for vacuumizing, filling epoxy resin doped with fluorescent powder for finishing impregnation, taking out the test piece slice after the impregnation is finished, coating a layer of epoxy resin on the observation surface of the test piece slice, standing for 35 minutes, scraping the residual epoxy resin on the surface, and performing secondary polishing on the test piece slice;

step three: specimen slice scanning

According to the second step, firstly, scanning panoramic microscopic images of sample slices with different rubber mixing amounts after secondary polishing through a full-automatic panoramic fluorescence microscope, obtaining the panoramic microscopic images of observation surfaces of the sample slices, and observing the porosity of the sample slices with different mixing amounts through the obtained panoramic microscopic images to obtain the influence of the mixing amount of the rubber particles on the mechanical property of the rubber concrete;

step four: test piece mesoscopic structure simulation

According to the third step, firstly, according to the panoramic microscopic image, the coarse aggregate and the rubber are put on a two-dimensional plane through Matlab software, the coarse aggregate is simplified into a polygon based on a real structure, the rubber is simplified into a circle for model building, then according to the distribution rule of the coarse aggregate and the rubber, a particle flow analysis program is compiled based on the Matlab software by means of a Monte Carlo method to generate a two-dimensional rubber concrete rubber and coarse aggregate structure model, the generated rubber and coarse aggregate particles are further subjected to position information and then are expanded to a certain width, then a program is compiled to generate a rubber-mortar interface and a coarse aggregate-mortar interface, after operation, the center coordinates and the radius of the rubber and rubber-mortar interface, the multipoint position coordinates of the coarse aggregate and coarse aggregate-mortar interface are obtained, then a language is parameterized and designed based on ANSYS software after the position coordinates of each phase of materials are obtained, and the mortar matrix and the, Establishing a coarse aggregate, a rubber-mortar interface transition area and a coarse aggregate-mortar interface transition area, and finally generating a rubber concrete mesoscopic structure model;

step five: analysis and comparison of real test and simulation experiment

According to the fourth step, firstly, a universal testing machine is adopted to carry out real fracture resistance tests on cubic test pieces with different rubber mixing amounts and record the test results, then the rubber concrete mesoscopic structure model is subjected to simulated fracture resistance tests according to the real tests and the test conclusions are stored, and then the real test results and the simulated test conclusions are compared and analyzed to obtain the relation between mesoscopic mechanics and macroscopic expressions of the rubber concrete fracture properties with different mixing amounts.

2. The method for mechanical analysis of microscopic fracture of rubber concrete with large content according to claim 1, wherein the method comprises the following steps: in the first step, the coarse aggregate is formed by mixing small limestone stones with the particle size of 5-10mm and large limestone stones with the particle size of 10-20mm in a ratio of 3:7, the rubber particles are rubber particles with the particle size of 3-6mm obtained by cutting waste tires, and the fine aggregate is natural river sand.

3. The method for mechanical analysis of microscopic fracture of rubber concrete with large content according to claim 1, wherein the method comprises the following steps: in the second step, in the polishing process of the sample slice, firstly polishing for 20 minutes by using the abrasive with the specification of 300#, then polishing for 10 minutes by using the abrasive with the specification of 800#, and finally polishing for 5 minutes by using the abrasive with the specification of 1000#, wherein the rotating speed of the automatic polishing machine is set to be 50r/min in the polishing process.

4. The method for mechanical analysis of microscopic fracture of rubber concrete with large content according to claim 1, wherein the method comprises the following steps: and in the second step, the vacuum degree in the vacuum drying oven is kept above 0.9, the temperature of the vacuum drying oven is set to be 40 ℃, sample slices are taken out every 6 hours in the drying process and weighed, and when the mass loss of the sample slices in 24 hours is less than 0.1g, the drying is finished.

5. The method for mechanical analysis of microscopic fracture of rubber concrete with large content according to claim 1, wherein the method comprises the following steps: in the third step, when the sample slice is scanned, the observation area of the selected sample slice is within the range of 90mm multiplied by 90mm, meanwhile, the observation area is equally divided into nine equal parts for observation, and the image obtained by scanning is formed by splicing nine sub-images of which the pixels are 12664 multiplied by 12664.

6. The method for mechanical analysis of microscopic fracture of rubber concrete with large content according to claim 1, wherein the method comprises the following steps: in the fourth step, a two-dimensional conversion formula which is derived by a Walraven J.C probability statistics-based method and accords with a three-dimensional Fuller grading curve is adopted to ensure the convenience of numerical simulation of the two-dimensional rubber concrete, and the formula is

In the formula P_cThe diameter d of any point on the cross section of the rubber concrete is less than d₀Probability of (P)_KThe volume of the particles is the percentage of the total volume of the rubber concrete, d is the actually required particle diameter of the particles, d₀For a defined particle size, d_maxThe largest particle size.

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