CN-116090174-B - Method for constructing dynamic hierarchical partition resource model of graphite

Abstract

The invention discloses a method for constructing a dynamic grading partition resource model of graphite, which comprises the following steps of obtaining basic information data of a graphite resource system, including geographical position information of a graphite resource distribution area, wherein the geographical position information comprises longitude and latitude, carrying out partition according to the position of the graphite resource, obtaining storage capacity of the graphite resource in different partitions, establishing a database for storage, further grading the partition area according to the existing content of the graphite resource, establishing an existing content model according to the content of the graphite resource in the grading area, obtaining consumption of the graphite resource in the grading area in the last ten years, and establishing an analysis model of different areas in a graphite consumption mode, and coupling the existing content model and the analysis model to obtain a dynamic model of the graphite resource grading partition, and reflecting the content curve of the graphite resource in the different areas in the ten years in the future and the graphite consumption mode.

Inventors

• WANG JIONGHUI
• CHEN DAOGUI
• CAO YI

Assignees

• 中国五矿集团(黑龙江)石墨产业有限公司

Dates

Publication Date

20260505

Application Date

20221201

Claims (7)

1. 1. A method for constructing a dynamic hierarchical partition resource model of graphite is characterized by comprising the following steps: The method comprises the steps of firstly, obtaining basic information data of a graphite resource system, wherein the basic information data comprises geographic position information of a graphite resource distribution area, and the geographic position information comprises basic characteristic parameters of longitude and latitude; dividing the sheet according to the position of the graphite resource; Step three, obtaining storage quantities of graphite resources in different areas, establishing a database for data storage, and further classifying and dividing the areas according to the existing content of the graphite resources; step four, establishing an existing content model according to the graphite resource content of the grading area; Acquiring consumption of graphite resources in a grading area in the last ten years, and establishing analysis models of different areas in a graphite consumption mode, wherein basic data of the analysis models comprise M, delta M and T, M is the content of the graphite resources in the different areas, delta M is the consumption of the graphite resources in the different areas, and T is time; and step six, coupling the existing content model and the analysis model to obtain a dynamic model of graphite resource grading and partitioning, and reflecting the content curves of graphite resources in different areas and the graphite consumption mode in the next ten years.
2. 2. The method for constructing a dynamic hierarchical zoning resource model of graphite of claim 1, wherein the analysis model is constructed by adding occasional values including the amount and manner of consumption of graphite resources unexpectedly consumed and the amount and manner of acquisition of graphite resources unexpectedly obtained.
3. 3. A method for constructing a dynamic hierarchical zoning resource model of graphite as set forth in claim 2 wherein the analysis of the data obtained is performed by comparing the data analysis method with the sensitivity analysis method when the analysis model is constructed, the analysis data including M, [ delta ] M, T, the amount of graphite unexpectedly consumed and the amount of graphite unexpectedly obtained.
4. 4. The method for constructing a dynamic hierarchical partition resource model of graphite as set forth in claim 1, wherein the residual contents of graphite resources in different areas within ten years of the future are calculated by simulation through the dynamic model of the hierarchical partition of graphite resources And a consumption rate v.
5. 5. A method for constructing a dynamic hierarchical zoning resource model of graphite according to claim 3, wherein the influence degree of the unexpectedly consumed graphite amount and the unexpectedly obtained graphite amount on the total content is studied from the quantitative analysis point of view when performing sensitivity analysis.
6. 6. The method for constructing a dynamic hierarchical partition resource model of graphite of claim 3, wherein the consumption, time and consumption modes are compared and compared in comparison data analysis, and whether the relationship of the consumption, time and consumption modes is coordinated or not is studied, and whether causal variables exist or not is determined.
7. 7. The method for constructing a dynamic hierarchical zoning resource model of graphite of claim 1, wherein the error of the area size between different zones is not more than 100m2.

Description

Method for constructing dynamic hierarchical partition resource model of graphite Technical Field The invention relates to the technical field of dynamic modeling, in particular to a method for constructing a dynamic hierarchical partition resource model of graphite. Background Dynamic models refer to models describing the equilibrium relationship between the components of the system and between the system and the outside as well as the course of motion of these relationships. The dynamic model can reflect the dynamic characteristics of the interaction of various factors in the motion change process of the system, and compared with the static model, the dynamic model adds time factors, so that the simulation of a real system can be more effectively realized. Along with the development of science and technology, the world industrial technology is accelerated to develop and transform towards the intelligent direction, and more operations need to construct dynamic models to achieve expected achievements. When a hierarchical zoning dynamic model is constructed for the distribution of graphite resources, a dynamic model which can truly reflect the storage capacity change of different areas and accurately simulate the residual quantity and consumption speed of graphite of different areas in the future needs to be established. Disclosure of Invention In order to overcome the defects of the prior art, the invention provides a method for constructing a dynamic graphite grading partition resource model, and the dynamic graphite resource grading partition model can accurately simulate and calculate the residual content M S and the consumption speed v of graphite resources in different areas in the next ten years. The method for constructing the graphite dynamic grading partition resource model comprises the following steps of obtaining basic information data of a graphite resource system, including geographic position information of a graphite resource distribution area, wherein the geographic position information comprises basic characteristic parameters of longitude and latitude, dividing the graphite resource according to the position of the graphite resource, obtaining storage capacity of different graphite resources in the different areas, establishing a database for data storage, further grading the areas according to the existing content of the graphite resource, establishing an existing content model according to the content of the graphite resource in the grading area, obtaining consumption of the graphite resource in the grading area in the last ten years, and establishing an analysis model of the different areas, and coupling the existing content model and the analysis model to obtain a dynamic model of the graphite resource grading partition, and reflecting the content curve of the graphite resource in the different areas and the graphite consumption mode in the ten years. As a preferable technical scheme of the invention, the basic data for establishing the analysis model comprise M, deltaM and T, wherein M is the graphite resource content of different areas, deltaM is the graphite resource consumption of different areas, and T is time. As a preferable technical scheme of the invention, when an analysis model is established, accidental values are added, including the accidental consumption of graphite resources and consumption modes, and the accidental acquisition of graphite resources and acquisition modes. As a preferred technical scheme of the invention, when an analysis model is established, the obtained data is analyzed by a comparison data analysis method and a sensitivity analysis method, and the analysis data comprise M, delta M, T, the accidentally consumed graphite amount and the accidentally obtained graphite amount. As a preferable technical scheme of the invention, the residual content M S and the consumption speed v of graphite resources in different areas in the next ten years are calculated through simulation by a dynamic model of graphite resource grading and partitioning. As a preferred technical scheme of the invention, in the sensitivity analysis, the influence degree of the accidentally consumed graphite amount and the accidentally obtained graphite amount on the total content is studied from the quantitative analysis perspective. As a preferable technical scheme of the invention, comparison data analysis is carried out, consumption, time and consumption modes are compared, whether the relationship of the consumption, the time and the consumption modes is coordinated or not is researched, and whether causal variables exist or not is researched. As a preferable technical scheme of the invention, when the areas are classified, the error of the area size between different areas is not more than 100m < 2 >. Compared with the prior art, the invention has the following beneficial effects: According to the construction method, the graphite resources are classified into the classified areas,