CN113567480B - Method for morphological analysis of main content element of non-ferrous metal concentrate - Google Patents

Abstract

The invention discloses a method for analyzing the form of main element content of non-ferrous metal concentrate, belonging to the technical field of element analysis, and the analyzing method comprises the following steps: (1) collecting and recording information of a non-ferrous metal concentrate sample; (2) analyzing the element content of the non-ferrous metal concentrate and carrying out classification marking; (3) detecting the classified elements and separating and extracting harmful elements; (4) collecting environmental information and constructing an environmental model for simulation test; (5) generating a waste treatment scheme according to the test data and feeding the waste treatment scheme back to the staff; the invention can automatically detect the element content of various non-ferrous metal concentrates, automatically record detection data at the same time, does not need manual detection and recording of workers, ensures the accuracy of data recording, prevents accidents of the workers in the detection process, protects the safety of the workers, prevents environmental pollution in the process of processing the metal concentrates, protects the natural environment and protects the health of residents.

Description

Method for morphological analysis of main content element of non-ferrous metal concentrate

Technical Field

The invention relates to the technical field of element analysis, in particular to a method for analyzing the form of main content elements of non-ferrous metal concentrate.

Background

The non-ferrous metal is a basic material and an important strategic material which are essential for the development of national economy, daily life of people and national defense industry and scientific technology, the agricultural modernization, the industrial modernization, the national defense and the scientific technology are not separated from the non-ferrous metal, along with the rapid advance of the modern chemical industry, the agricultural technology and the scientific technology, the position of the non-ferrous metal in the development of human beings is more and more important, the non-ferrous metal is not only an important strategic material and an important production material in the world, but also an important material of consumption materials which are indispensable in the life of human beings, the development of the non-ferrous metal industry of China is rapid in nearly 30 years, the yield is the top of the world in successive years, the non-ferrous metal science and technology plays an increasingly important role in the construction of national economy and the modern national defense, and simultaneously, the contradiction between the shortage of non-ferrous metal resources and the development demand of the national economy is increasingly prominent, the dependence degree on foreign resources is increased year by year, and the healthy development of national economy of China is seriously influenced; therefore, the invention of a method for analyzing the form of the main content element of the non-ferrous metal concentrate becomes more important;

through retrieval, Chinese patent No. CN110161067A discloses a concentrate metal content determination method based on portable XRF, which can quickly and economically realize multi-element metal content analysis in a field concentrate production place and greatly improve the accuracy of a portable XRF measurement result, but cannot analyze the pollution of harmful elements in metal concentrate to the surrounding environment, easily causes environmental pollution in the process of treating the metal concentrate, and destroys the natural environment; in addition, the existing method for analyzing the main content element morphology of the nonferrous metal concentrate needs workers to manually detect and record data, so that the data record is easy to deviate, and the working efficiency of the workers is reduced; therefore, a method for analyzing the form of the main element content of the nonferrous metal concentrate is provided.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides a method for analyzing the form of main content elements of non-ferrous metal concentrate.

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

a method for analyzing the form of main element content of non-ferrous metal concentrate comprises the following steps:

(1) collecting and recording information of non-ferrous metal concentrate samples: the method comprises the steps that computing equipment receives nonferrous metal concentrate sample information uploaded by workers, carries out sample classification processing on the nonferrous metal concentrate samples according to the information uploaded by the workers, simultaneously generates a recording table, and records the nonferrous metal concentrate information into the recording table, wherein the computing equipment is specifically one of a notebook computer or a desktop computer;

(2) analyzing element content of the non-ferrous metal concentrate and carrying out classification marking: the analysis system comprises a calculation device, an analysis device, a data recording and processing module, a data transmission module, a data analysis module, a waste processing module and a data transmission module, wherein the calculation device is in communication connection with the analysis system and starts to send a detection instruction to the analysis system, the analysis device receives the detection instruction and starts to perform element content detection on the nonferrous metal concentrate, the detected elements are subjected to data analysis, and relevant information of the elements is recorded into a recording table;

(3) detecting the classified elements and separating and extracting harmful elements: carrying out data detection on the classified element information, labeling harmful elements in the classified element information, and simultaneously controlling the analysis equipment to separate and extract the harmful elements by the computing equipment;

(4) collecting environmental information and constructing an environmental model for simulation test: collecting surrounding environment information, starting to construct an environment model, importing harmful element information into the environment model, and starting to operate the environment model for simulation test;

(5) generating a waste treatment scheme according to the test data and feeding back the waste treatment scheme to the staff: and after the simulation test is finished, the computing equipment intelligently formulates a waste treatment scheme according to the test data, the formulation of the scheme is finished, and the computing equipment feeds the waste treatment scheme back to the working personnel.

Further, the classification processing in the step (1) specifically comprises the following steps:

the method comprises the following steps: the computing equipment receives the nonferrous metal concentrate sample information uploaded by the staff and starts to be in communication connection with the network information sharing platform;

step two: analyzing the information of the non-ferrous metal concentrate sample, and retrieving corresponding non-ferrous metal information from a network information sharing platform;

step three: classifying the non-ferrous metal concentrate samples according to different types, counting the number of various non-ferrous metal concentrates, simultaneously generating a record table, and recording the names and the number of various non-ferrous metal concentrates into the record table.

Further, the content detection in the step (2) comprises the following specific steps:

the first step is as follows: the calculation equipment completes the statistics of the information of the non-ferrous metal concentrate sample, and starts to issue a detection instruction to an analysis system according to sampling and sample preparation standards specified in GB/T2007.1-1987 and GB/T2007.2-1987;

the second step is that: the conveying module receives the detection instruction and transports the non-ferrous metal concentrate samples in order, the crushing module receives the non-ferrous metal concentrate samples, dries and crushes the non-ferrous metal concentrate samples, and the non-ferrous metal concentrate samples are screened by a standard sieve with the diameter of 38 mu m after being crushed;

the third step: the detection module extracts a non-ferrous metal concentrate sample, performs element content detection through the array detector and the X-ray diffractometer, and feeds back the content of each element to the computing equipment.

Further, the specific steps of the separation and extraction in the step (3) are as follows:

s1: the computing equipment receives the content information of each element, records the content information into a record table, detects harmful elements in the record table, marks the detected harmful elements in the record table and issues a separation instruction;

s2: the separation module receives the separation instruction, starts to separate the harmful elements and transmits the harmful elements to the waste treatment module for storage.

Further, the simulation test in the step (4) specifically comprises the following steps:

SS 1: the method comprises the following steps that a worker collects surrounding environment information and uploads the surrounding environment information to computing equipment, the uploading of the environment information is completed, and the computing equipment starts to construct an environment model;

SS 2: harmful element information is imported into an environment model, a worker starts to set simulation running time X, and the environment model starts to run;

SS 3: and when the running time is reached, the environment model feeds the test data back to the computing equipment, and the computing equipment receives the test data and records the test data into the record table.

Further, the intelligent waste treatment scheme establishment in the step (5) comprises the following specific steps:

p1: after the data recording is finished, marking elements which can generate environmental pollution;

p2: the method comprises the following steps that a computing device begins to capture a corresponding element processing mode in a network information sharing platform, begins to make a corresponding waste processing scheme according to captured information, and sends a generated processing scheme to a waste processing module;

p3: the waste treatment module starts to purify the relevant elements according to a waste treatment scheme;

p4: and inputting the purified data into a record table, and simultaneously feeding the record table back to a worker, wherein the worker can process the rest elements according to the record table.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the method for analyzing the form of the main content element of the non-ferrous metal concentrate, working personnel input non-ferrous metal concentrate information into computing equipment, and the computing equipment begins to classify the non-ferrous metal concentrate according to different types. The data volume of various non-ferrous metal concentrates is counted, a recording table is generated, a detection instruction is issued to an analysis system according to sampling and sample preparation standards specified in GB/T2007.1-1987 and GB/T2007.2-1987, the analysis system starts to perform element analysis on the non-ferrous metal concentrates and automatically feeds back the information and the content of each element to a computing device, the computing device receives feedback data and records the feedback data into the recording table, the element content detection can be automatically performed on various non-ferrous metal concentrates, the detection data are automatically recorded, manual detection and recording of workers are not needed, the accuracy of data recording is guaranteed, accidents of the workers in the detection process are prevented, and the safety of the workers is protected;

2. the method for analyzing the form of the main content element of the nonferrous metal concentrate comprises the steps that a computing device records information and content of each element into a recording table, marks harmful elements in the recording table, a worker uploads surrounding environment information, the computing device starts to build an environment model according to the environment information uploaded by the worker, introduces the harmful element information into the environment model for simulation test, feeds test data back to the computing device, the computing device starts to grab a corresponding element processing mode in a network information sharing platform, starts to make a corresponding waste processing scheme according to the grabbed information, simultaneously sends the generated processing scheme to a waste processing module, the waste processing module starts to purify and process related elements according to the waste processing scheme, can analyze pollution of the harmful elements in the metal concentrate to the surrounding environment, and automatically makes the processing scheme, the method prevents environmental pollution in the process of treating the metal concentrate, protects the natural environment and protects the health of residents.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

FIG. 1 is a flow chart of a method for morphological analysis of main content elements of non-ferrous metal concentrates, which is provided by the invention.

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.

Example 1

Referring to fig. 1, a method for analyzing the morphology of a main element content of a non-ferrous metal concentrate includes the following steps:

s1, collecting and recording information of the nonferrous metal concentrate sample: the computing equipment receives the information of the nonferrous metal concentrate samples uploaded by the staff, carries out sample classification processing on the nonferrous metal concentrate samples according to the information uploaded by the staff, generates a record table at the same time, and records the information of each nonferrous metal concentrate into the record table;

s2, analyzing the element content of the non-ferrous metal concentrate and carrying out classification marking: the computing equipment starts to be in communication connection with the analysis system and starts to send a detection instruction to the analysis system, the analysis equipment receives the detection instruction and starts to detect the element content of the nonferrous metal concentrate, the detected elements are subjected to data analysis, and the related information of the elements is recorded into a recording table.

S3, detecting the classified elements and separating and extracting harmful elements: and carrying out data detection on the classified element information, labeling harmful elements in the classified element information, and simultaneously controlling the analysis equipment to separate, extract and process the harmful elements by the computing equipment.

Specifically, during operation, firstly, the computing equipment receives nonferrous metal concentrate sample information uploaded by workers, starts communication connection with the network information sharing platform, analyzes the nonferrous metal concentrate sample information, retrieves corresponding nonferrous metal information from the network information sharing platform, classifies the nonferrous metal concentrate samples according to different types, counts the number of various nonferrous metal concentrates, generates a record table at the same time, records the names and the number of various nonferrous metal concentrates into the record table to complete classification, and then, when the computing equipment completes the statistics of the nonferrous metal concentrate sample information, starts to issue detection instructions to an analysis system according to sampling and sample preparation standards specified in GB/T2007.1-1987 and GB/T2007.2-1987, the conveying module receives the detection instructions and transports the nonferrous metal concentrate samples in order, the crushing module receives a non-ferrous metal concentrate sample, dries and crushes the non-ferrous metal concentrate sample, finishes crushing, screens the non-ferrous metal concentrate sample through a 38 mu m standard sieve, extracts the non-ferrous metal concentrate sample, starts element content detection through an array detector and an X-ray diffractometer, finally feeds back the element content to computing equipment, the computing equipment receives the element content information, records the element content information into a recording table, detects harmful elements in the recording table, marks the detected harmful elements in the recording table after detection is finished, sends a separation instruction, receives the separation instruction, starts to separate the harmful elements, transmits the harmful elements to a waste processing module for storage, can realize that the computing equipment automatically detects the element content of various non-ferrous metal concentrates, and automatically records detection data without manual detection and recording of workers, the accuracy of data record has been guaranteed, prevents simultaneously that the staff from appearing the accident in the testing process, and protection staff safety can carry out the analysis to harmful element in the metal concentrate to environmental pollution on every side, and formulate processing scheme by oneself, prevent to cause environmental pollution at the in-process of handling the metal concentrate, protection natural environment, the protection resident is healthy.

In this embodiment, the computing device is specifically one of a notebook computer or a desktop computer, and the analysis system is specifically composed of a conveying module, a crushing module, a detection module, a separation module, a waste treatment module, and a data transmission module.

It should be further noted that the working principle of the X-ray diffractometer is to detect the metal constituent elements by the fluctuating property and particle property of the X-rays, wherein the X-rays are electromagnetic waves or electromagnetic radiation which are identical to visible light in nature, but the X-rays are generated by the action of high-speed charged particles and inner layer electrons in material atoms, so that the energy is large, the wavelength is short, and the ability of penetrating the material is strong.

Example 2

Referring to fig. 1, a method for analyzing the morphology of a main element content of a non-ferrous metal concentrate, the analyzing method further comprises the following steps:

s4, collecting environmental information and constructing an environmental model for simulation test: and collecting surrounding environment information, starting to construct an environment model, importing harmful element information into the environment model, and starting to operate the environment model for simulation test.

S5, generating a waste treatment scheme according to the test data and feeding the waste treatment scheme back to the staff: and after the simulation test is finished, the computing equipment intelligently formulates a waste treatment scheme according to the test data, the formulation of the scheme is finished, and the computing equipment feeds the waste treatment scheme back to the working personnel.

Specifically, firstly, the staff needs to collect the surrounding environment information and upload the information to the computing equipment, the environment information is uploaded completely, the computing equipment starts to construct an environment model, harmful element information is led into the environment model, the staff starts to set simulation running time X, the environment model starts to run and reaches the running time, the environment model feeds back test data to the computing equipment, the computing equipment receives the test data and records the test data into a record table, the data record is completed, elements which can generate environmental pollution are marked, secondly, the computing equipment starts to grab corresponding element processing modes in a network information sharing platform and starts to make corresponding waste processing schemes according to the grabbed information, meanwhile, the generated processing schemes are sent to a waste processing module, and the waste processing module starts to purify the relevant elements according to the waste processing schemes, in the data entry record table that will purify the completion, feed back the record table to the staff simultaneously, the staff can handle the operation to surplus element according to the record table, can carry out the analysis to harmful element in the metal concentrate to ambient environmental pollution, and formulate processing scheme by oneself, prevent to cause environmental pollution at the in-process of handling the metal concentrate, protect natural environment, the protection resident is healthy.

It should be further noted that, after the operator inputs the running time X through the external input device, the environment model starts to simulate the change of the area environment and the influence on people living in the area after harmful elements enter the environment for X years, and the test data is fed back to the computing device.

The external input device in this embodiment is specifically a keyboard, an electronic pen, and a touch screen.

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 considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (4)

1. A method for analyzing the form of main element content of non-ferrous metal concentrate is characterized by comprising the following steps:

(1) collecting and recording information of non-ferrous metal concentrate samples: the method comprises the steps that computing equipment receives nonferrous metal concentrate sample information uploaded by workers, carries out sample classification processing on the nonferrous metal concentrate samples according to the information uploaded by the workers, simultaneously generates a recording table, and records the nonferrous metal concentrate information into the recording table, wherein the computing equipment is specifically one of a notebook computer or a desktop computer;

(2) analyzing element content of the non-ferrous metal concentrate and carrying out classification marking: the analysis system comprises a calculation device, an analysis device, a data recording and processing module, a data transmission module, a data analysis module, a waste processing module and a data transmission module, wherein the calculation device is in communication connection with the analysis system and starts to send a detection instruction to the analysis system, the analysis device receives the detection instruction and starts to perform element content detection on the nonferrous metal concentrate, the detected elements are subjected to data analysis, and relevant information of the elements is recorded into a recording table;

(3) detecting the classified elements and separating and extracting harmful elements: carrying out data detection on the classified element information, labeling harmful elements in the classified element information, and simultaneously controlling the analysis equipment to separate, extract and process the harmful elements by the computing equipment;

(4) collecting environmental information and constructing an environmental model for simulation test: collecting surrounding environment information, starting to construct an environment model, importing harmful element information into the environment model, and starting to operate the environment model for simulation test;

(5) generating a waste treatment scheme according to the test data and feeding back the waste treatment scheme to the staff: after the simulation test is finished, the computing equipment intelligently formulates a waste treatment scheme according to the test data, the formulation of the scheme is finished, and the computing equipment feeds the waste treatment scheme back to the staff;

the simulation test comprises the following specific steps:

SS 1: the method comprises the following steps that a worker collects surrounding environment information and uploads the surrounding environment information to computing equipment, the uploading of the environment information is completed, and the computing equipment starts to construct an environment model;

SS 2: harmful element information is imported into an environment model, a worker starts to set simulation running time X, and the environment model starts to run;

SS 3: when the running time is reached, the environment model feeds back the test data to the computing equipment, and the computing equipment receives the test data and records the test data into a record table;

the intelligent waste treatment scheme comprises the following specific steps:

p1: after the data recording is finished, marking elements which can generate environmental pollution;

p2: the method comprises the following steps that a computing device begins to capture a corresponding element processing mode in a network information sharing platform, begins to make a corresponding waste processing scheme according to captured information, and sends a generated processing scheme to a waste processing module;

p3: the waste treatment module starts to purify the relevant elements according to a waste treatment scheme;

p4: and inputting the purified data into a record table, and simultaneously feeding the record table back to a worker, wherein the worker can process the rest elements according to the record table.

2. The method for the morphological analysis of the main content elements of the nonferrous metal concentrate according to claim 1, wherein the classification treatment in the step (1) comprises the following specific steps:

the method comprises the following steps: the computing equipment receives the nonferrous metal concentrate sample information uploaded by the staff and starts to be in communication connection with the network information sharing platform;

step two: analyzing the information of the non-ferrous metal concentrate sample, and retrieving corresponding non-ferrous metal information from a network information sharing platform;

step three: classifying the non-ferrous metal concentrate samples according to different types, counting the number of various non-ferrous metal concentrates, simultaneously generating a record table, and recording the names and the number of various non-ferrous metal concentrates into the record table.

3. The method for the morphological analysis of the main content elements of the nonferrous metal concentrate according to claim 1, wherein the content detection in the step (2) comprises the following specific steps:

the first step is as follows: the calculation equipment completes the statistics of the information of the non-ferrous metal concentrate sample, and starts to issue a detection instruction to an analysis system according to sampling and sample preparation standards specified in GB/T2007.1-1987 and GB/T2007.2-1987;

the second step: the conveying module receives the detection instruction and transports the non-ferrous metal concentrate samples in order, the crushing module receives the non-ferrous metal concentrate samples, dries and crushes the non-ferrous metal concentrate samples, and the non-ferrous metal concentrate samples are screened by a standard sieve with the diameter of 38 mu m after being crushed;

the third step: the detection module extracts a non-ferrous metal concentrate sample, performs element content detection through the array detector and the X-ray diffractometer, and feeds back the content of each element to the computing equipment.

4. The method for the morphological analysis of the main content of elements in the nonferrous metal concentrate according to claim 1, wherein the separation and extraction in the step (3) comprises the following specific steps:

s1: the computing equipment receives the content information of each element, records the content information into a record table, detects harmful elements in the record table, marks the detected harmful elements in the record table and issues a separation instruction;

s2: the separation module receives the separation instruction, starts to separate the harmful elements and transmits the harmful elements to the waste treatment module for storage.

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