CN113376349A

CN113376349A - Analysis system for performance detection data of high-end equipment manufacturing material

Info

Publication number: CN113376349A
Application number: CN202110639984.8A
Authority: CN
Inventors: 罗玉梅; 王博; 靳予记; 许洋洋; 王莹
Original assignee: Zhengzhou University of Industrial Technology
Current assignee: Zhengzhou University of Industrial Technology
Priority date: 2021-06-08
Filing date: 2021-06-08
Publication date: 2021-09-10

Abstract

The invention discloses an analysis system for high-end equipment manufacturing material performance detection data, and belongs to the technical field of material performance detection. An analysis system for high-end equipment manufacturing material performance testing data, comprising: a material selection module, a test and test module, and a data analysis module; the material selection module is used for inputting basic properties of materials; the test and test module , which is used to test the performance of materials in various aspects; the data analysis module is used to process, analyze and manage the performance data of materials; the material selection module includes: material type unit, material specification unit and material quality unit ; the material type unit is used to select the corresponding material type option according to the testing material; the material specification unit is used to input the specification information such as the length, width, height or radius of the material; the performance testing test of the present invention is rich and diverse, and the data It is convenient to organize, compare and analyze, and manage the material performance data conveniently.

Description

Analysis system for performance detection data of high-end equipment manufacturing material

Technical Field

The invention relates to the technical field of material performance detection, in particular to an analysis system for performance detection data of a manufacturing material of high-end equipment.

Background

The material performance detection is to perform test detection on the performance data of the material to summarize the standards of the performance of each aspect of the material, so as to complete the set rule of the material quality.

In order to detect the performance of the manufacturing material of high-end equipment, a data sorting and analyzing system which is convenient to adapt to various material performance detection tests is designed.

Disclosure of Invention

The invention aims to solve the problems that a performance detection test of a material is single, data is difficult to sort, compare and analyze, and management of material performance data is inconvenient in the performance detection process, and provides an analysis system for the performance detection data of a high-end equipment manufacturing material.

In order to achieve the purpose, the invention adopts the following technical scheme:

an analysis system for high end equipment manufacturing material property detection data, comprising: the device comprises a material selection module, a test testing module and a data analysis module;

the material selection module is used for inputting basic characteristics of the material; the test module is used for carrying out performance detection on various aspects on the material; the data analysis module is used for processing, analyzing and managing the performance data of the material;

the material selection module comprises: a material type unit, a material specification unit and a material quality unit;

the material type unit is used for selecting a corresponding material type option according to the detected material; the material specification unit is used for inputting specification information such as length, width, height or radius of the material; and the material quality unit is used for recording data for weighing the material.

Preferably, the test module comprises a mechanical test unit, a metallographic test unit, a corrosion test unit and a nondestructive inspection unit;

the mechanical testing unit is used for testing the mechanical property of the material; the metallographic test unit is used for establishing a quantitative relation among alloy components, structures and properties; the corrosion testing unit is used for mastering the characteristics of a corrosion system formed by materials and the environment; the nondestructive inspection unit is used for detecting cracks or defects in the metal material or the part.

Preferably, the mechanical testing unit comprises a compression testing subunit, a cutting testing subunit, a friction testing subunit, a torsion testing subunit, a tension testing subunit and an impact testing subunit.

Preferably, the metallographic test unit comprises a port inspection subunit and a PCB metallographic section subunit.

Preferably, the corrosion test unit comprises a salt spray test subunit, a sulfur dioxide corrosion test subunit, a hydrogen sulfide corrosion test subunit and a mixed gas corrosion test subunit.

Preferably, the nondestructive inspection unit comprises an ultrasonic detection subunit and an X-ray detection subunit.

Preferably, the data analysis module comprises an image acquisition unit, an image processing and analyzing unit, a data management unit and a report printing unit.

The image acquisition unit is used for acquiring and inputting test information of the material; the image processing and analyzing unit is used for processing and analyzing the collected images; the data management unit is used for storing the performance data of the material; and the report printing unit is used for printing the performance data report of the material.

Preferably, the image processing and analyzing unit comprises a diffraction analysis method subunit, an electron energy spectrum analysis method subunit, a spectrum analysis method subunit, an electron microscopy analysis method subunit and an electrochemical analysis method subunit.

Compared with the prior art, the invention provides an analysis system for performance detection data of a high-end equipment manufacturing material, which has the following beneficial effects:

1. through the arrangement of the material selection module, the type, specification and weight of the material can be accurately recorded and calculated, so that standard comparison data is generated, and whether the quality of the material reaches the standard or not is judged;

2. through the arrangement of the test module, a user can effectively and conveniently perform detection tests on various functional performances of the material, so that the integrity of material data acquisition can be improved, the material can be subjected to mechanical performance detection, metallographic test, corrosion test and nondestructive inspection test, and various requirements of the user are met;

3. through the setting of data analysis module, can carry out comprehensive comparison analysis to the data of gathering to accomplish the quality ratio to the material, accomplish data arrangement and analysis to the material.

Drawings

FIG. 1 is a schematic diagram of a system control frame structure of a material property detection system based on virtual reality technology according to the present invention;

FIG. 2 is a schematic flow chart of a test module of a material property detection system based on a virtual reality technology according to the present invention;

fig. 3 is a schematic flow chart of a data analysis module of a material property detection system based on a virtual reality technology according to the present invention.

In the figure: 1. a material selection module; 101. a material type unit; 102. a material specification unit; 103. a material mass unit; 2. a test testing module; 201. a mechanical test unit; 202. a metallographic test unit; 203. a corrosion test unit; 204. a nondestructive inspection unit; 3. a data analysis module; 301. collecting an image unit; 302. an image processing and analyzing unit; 303. a data management unit; 304. and a report printing unit.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Referring to fig. 1-3, an analysis system for performance test data of high-end equipment manufacturing materials includes: the device comprises a material selection module 1, a test testing module 2 and a data analysis module 3;

the material selection module 1 is used for inputting basic characteristics of materials; the test module 2 is used for carrying out performance detection on various aspects of the material; the data analysis module 3 is used for processing, analyzing and managing the performance data of the material;

the material selection module 1 comprises: a material type unit 101, a material specification unit 102, and a material quality unit 103;

a material type unit 101 for selecting a corresponding material type option according to the detected material; the material specification unit 102 is used for inputting specification information such as length, width, height or radius of a material; and the material quality unit 103 is used for recording data for weighing the material.

Further, the test module 2 comprises a mechanical test unit 201, a metallographic test unit 202, a corrosion test unit 203 and a nondestructive inspection unit 204;

a mechanical testing unit 201 for testing the mechanical properties of the material; the metallographic test unit 202 is used for establishing quantitative relations among alloy components, structures and properties; a corrosion test unit 203 for grasping characteristics of a corrosion system composed of a material and an environment; and a nondestructive inspection unit 204 for detecting cracks or defects inside the metallic material or the component.

Further, the mechanical testing unit 201 includes a compression testing subunit, a cutting testing subunit, a friction testing subunit, a torsion testing subunit, a tension testing subunit, and an impact testing subunit.

Further, the metallographic test unit 202 includes a port inspection subunit and a PCB microsection subunit.

Further, the corrosion test unit 203 includes a salt spray test subunit, a sulfur dioxide corrosion test subunit, a hydrogen sulfide corrosion test subunit, and a mixed gas corrosion test subunit.

Further, the nondestructive inspection unit 204 includes an ultrasonic inspection subunit and an X-ray inspection subunit.

Further, the data analysis module 3 includes an image capturing unit 301, an image processing and analyzing unit 302, a data management unit 303, and a report printing unit 304.

The image acquisition unit 301 is used for acquiring and inputting test information of the material; an image processing and analyzing unit 302 for processing and analyzing the collected images; a data management unit 303 for storing performance data of the material; and a report printing unit 304 for printing the performance data report of the material.

Further, the image processing and analyzing unit 302 includes a diffraction analysis method subunit, an electron energy spectrometry analysis method subunit, a spectroscopic analysis method subunit, an electron microscopy analysis method subunit, and an electrochemical analysis method subunit.

According to the invention, through the arrangement of the material selection module 1, the type, specification and weight of the material can be accurately recorded and calculated, so that a standard comparison data is generated, and whether the quality of the material reaches the standard or not is judged;

through the arrangement of the test module 2, a user can effectively and conveniently perform detection tests on various functional performances of the material, so that the integrity of material data acquisition can be improved, the material can be subjected to mechanical performance detection, metallographic test, corrosion test and nondestructive inspection test, and various requirements of the user are met;

through the setting of the data analysis module 3, the collected data can be comprehensively compared and analyzed so as to finish the quality evaluation of the material and finish the data sorting and analysis of the material.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.

Claims

1. a material performance detection system based on virtual reality technology, is characterized in that, comprises: material selection module (1), experiment test module (2) and data analysis module (3);

The material selection module (1) is used for inputting the basic properties of the material; the experimental testing module (2) is used for performing performance testing on the material in various aspects; the data analysis module (3) is used for Process, analyze and manage material performance data;

The material selection module (1) includes: a material type unit (101), a material specification unit (102) and a material quality unit (103);

The material type unit (101) is used to select a corresponding material type option according to the detected material; the material specification unit (102) is used to input specification information such as length, width, height or radius of the material; the material quality The unit (103) is used for inputting the data of weighing the material.

2. A material property detection system based on virtual reality technology according to claim 1, characterized in that, the test test module (2) comprises a mechanical test unit (201), a metallographic test unit (202), a corrosion a testing unit (203) and a non-destructive testing unit (204);

The mechanical test unit (201) is used to test the mechanical properties of the material; the metallographic test unit (202) is used to establish a quantitative relationship between alloy composition, structure and properties; the corrosion test unit (203) ), which is used to grasp the characteristics of the corrosion system formed by the material and the environment; the non-destructive testing unit (204) is used to detect the cracks or defects inside the metal material or the component.

3. A material property detection system based on virtual reality technology according to claim 2, wherein the mechanical test unit (201) comprises a compression test subunit, a cutting test subunit, a friction test subunit, a torsion test subunit, and a torsion test subunit. Test sub-unit, tensile test sub-unit and impact test sub-unit.

4 . The material property detection system based on virtual reality technology according to claim 2 , wherein the metallographic testing unit ( 202 ) comprises a port inspection sub-unit and a PCB metallographic slicing sub-unit. 5 .

5. A material performance detection system based on virtual reality technology according to claim 2, wherein the corrosion test unit (203) comprises a salt spray test subunit, a sulfur dioxide corrosion test subunit, and a hydrogen sulfide corrosion test Subunit and Mixed Gas Corrosion Test Subunit.

6 . The material property detection system based on virtual reality technology according to claim 2 , wherein the non-destructive flaw detection unit ( 204 ) comprises an ultrasonic detection sub-unit and an X-ray detection sub-unit. 7 .

7. A material property detection system based on virtual reality technology according to claim 1, wherein the data analysis module (3) comprises an image acquisition unit (301), an image processing and analysis unit (302), a data analysis unit (302), a Management unit (303) and report printing unit (304).

The image acquisition unit (301) is used to collect and input test information of the material; the image processing and analysis unit (302) is used to process and analyze the collected images; the data management unit (303) is used for for storing the performance data of the material; the report printing unit (304) is used for printing the performance data report of the material.

8. a kind of material property detection system based on virtual reality technology according to claim 7, is characterized in that, described image processing analysis unit (302) comprises diffraction analysis method subunit, electron energy spectrum analysis method subunit, spectral analysis method subunit Unit, Electron Microanalysis Subunit and Electrochemical Analysis Subunit.