CN116401793A - Grinding tool three-dimensional model construction method based on grinding tool design - Google Patents

Grinding tool three-dimensional model construction method based on grinding tool design Download PDF

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CN116401793A
CN116401793A CN202310663971.3A CN202310663971A CN116401793A CN 116401793 A CN116401793 A CN 116401793A CN 202310663971 A CN202310663971 A CN 202310663971A CN 116401793 A CN116401793 A CN 116401793A
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grinding tool
dimensional model
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abrasive
grinding
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CN116401793B (en
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徐恩成
徐长红
李庆
冯新刚
徐炳明
高勇
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Jining Lianwei Wheel Manufacturing Co ltd
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Abstract

The invention discloses a grinding tool three-dimensional model construction method based on grinding tool design, which particularly relates to the field of three-dimensional model construction, and comprises the steps of grinding tool three-dimensional model construction, grinding tool three-dimensional model information acquisition, grinding tool three-dimensional model information processing, grinding tool quality analysis, grinding tool three-dimensional model part supervision, grinding tool quality assessment and grinding tool three-dimensional model safety supervision.

Description

Grinding tool three-dimensional model construction method based on grinding tool design
Technical Field
The invention relates to the technical field of three-dimensional model construction, in particular to a grinding tool three-dimensional model construction method based on grinding tool design.
Background
The method has the advantages that the production efficiency of the product is greatly improved by using the grinding tool to process the product, raw materials are saved, the energy consumption and the cost are reduced, the consistency of the product is maintained, the product is processed by using the die to become an important component part of a production and processing enterprise, along with the high-speed development of the software and hardware technology of a computer, the traditional die design method cannot adapt to the requirements of updating and upgrading the product and improving the quality, the three-dimensional modeling technology can realistically restore the real scene in the computer, the real feeling is brought to the user in the virtual environment, the three-dimensional effect graph of the design scheme can be obtained through the coloring and rendering functions, the size, the quality and the manufacturing cost of the product can be comprehensively and accurately known without making the real grinding tool, the design decision is facilitated, and the product development process of the enterprise is promoted.
However, when the grinding tool is actually used, the method still has some defects, such as that the traditional grinding tool production method is to produce a model with the same proportion according to a design scheme, and multiple tests and modifications can be carried out, so that the method can consume a great deal of time and labor cost, the production and manufacturing cost of enterprises is increased, and the production efficiency of the enterprises is reduced;
the method is limited by the capability of technicians, complex shapes cannot be manually adjusted, the accuracy of the model is difficult to guarantee by manual operation, the uniformity of the model is difficult to guarantee, the risk of leakage of a grinding tool design draft exists in manual operation, the grinding tool design draft is stolen and utilized by lawless persons, the quality of products is affected, and then the public praise of enterprises is threatened, and the development of the enterprises is affected.
Disclosure of Invention
In order to overcome the above-mentioned drawbacks of the prior art, an embodiment of the present invention provides a three-dimensional model construction method for an abrasive tool based on an abrasive tool design, which is used for solving the problems set forth in the above-mentioned background art.
In order to achieve the above purpose, the present invention provides the following technical solutions:
step S01: constructing a three-dimensional model of the grinding tool: specifically, the method comprises the steps of obtaining a grinding tool design drawing of a target enterprise, importing the grinding tool design drawing into a network terminal, synthesizing a three-dimensional model of the grinding tool by using computer software, and sequentially recording as 1 and 2 … … n.
Step S02: and (3) acquiring information of a three-dimensional model of the grinding tool: the method is specifically used for setting observation points, and collecting the number of parts, the number of key parts, the number of grinding tool manufacturing, the amount of grinding tool manufacturing, the quality of the grinding tool and the volume of the grinding tool of a target enterprise grinding tool three-dimensional model.
Step S03: and (3) processing information of the three-dimensional model of the grinding tool: the method specifically comprises the steps of receiving data information transmitted by three-dimensional model information acquisition of the grinding tool, calculating the key part efficiency index of the grinding tool through the number of parts, the number of key parts and the manufacturing number of the grinding tool, and calculating the production influence index of the grinding tool through the amount of the manufactured grinding tool, the quality of the grinding tool and the volume of the grinding tool.
Step S04: grinding tool mass analysis: the method specifically comprises the steps of receiving data information transmitted by processing the three-dimensional model information of the grinding tool, and calculating the efficiency index of key parts of the grinding tool and the production influence index of the grinding tool to obtain the quality evaluation coefficient of the grinding tool.
Step S05: monitoring three-dimensional model parts of grinding tools: the method comprises the steps of receiving data information transmitted by the information processing of the three-dimensional model of the grinding tool, comparing the efficiency index of the key part of the grinding tool with the preset efficiency index of the key part of the grinding tool, carrying out detail processing of the three-dimensional model according to the result, and carrying out numbering early warning display on the three-dimensional model of the grinding tool in an abnormal state.
Step S06: grinding tool quality evaluation: specifically, the grinding tool quality evaluation coefficient of the three-dimensional model of the target enterprise grinding tool is obtained, the grinding tool quality evaluation coefficient is compared with a preset grinding tool quality evaluation coefficient, if the grinding tool quality of the three-dimensional model of the target enterprise grinding tool is smaller than a preset value, the abnormal model is immediately numbered and displayed, the result is sent to an enterprise terminal, and a designer modifies a corresponding drawing.
Step S07: safety supervision of three-dimensional model of grinding tool: the method is characterized in that a three-dimensional model and a design drawing of a target enterprise grinding tool are stored, and meanwhile data encryption is carried out through an RSA algorithm in the data transmission process.
The three-dimensional model of the grinding tool is constructed specifically as follows:
obtaining a grinding tool design drawing of a target enterprise, importing the drawing into computer modeling software to generate a three-dimensional model of the grinding tool, and optimizing the generated three-dimensional model, wherein the three-dimensional model comprises the steps of noise reduction, smooth surface, hole filling, hole removal, superposition removal and operation, and is sequentially recorded as 1 n and 2 n … … n.
The specific acquisition mode of the three-dimensional model information acquisition of the grinding tool is as follows:
and setting observation points on the three-dimensional model of the target enterprise grinding tool, and collecting the number of parts, the number of key parts, the number of grinding tool manufacturing, the amount of grinding tool manufacturing, the quality of the grinding tool and the volume of the grinding tool of the target enterprise grinding tool, wherein the numbers are pl, pg, zg, zm, zf and pz respectively.
The calculation formula of the efficiency index of the key parts of the grinding tool is as follows:
Figure SMS_1
*/>
Figure SMS_2
+/>
Figure SMS_3
*/>
Figure SMS_4
wherein->
Figure SMS_5
Expressed as an efficiency index of key parts of the grinding tool, pl expressed as the number of parts, pg expressed as the number of key parts, zg expressed as the number of grinding tool manufacture, e expressed as a natural constant,/>
Figure SMS_6
、/>
Figure SMS_7
Expressed as the number of parts, and the number of abrasive articles made, respectively.
The calculation formula of the grinding tool production influence index is as follows:
Figure SMS_10
+/>
Figure SMS_13
+/>
Figure SMS_18
+/>
Figure SMS_8
wherein->
Figure SMS_14
Expressed as a grinding tool production influence index, zm is expressed as the amount of grinding tool to be manufactured, < >>
Figure SMS_17
Representing the preset amount of the grinding tool to be manufactured, +.>
Figure SMS_20
Expressed as the mass of the abrasive article,
Figure SMS_11
expressed as preset abrasive mass, +.>
Figure SMS_15
Expressed as abrasive volume>
Figure SMS_16
Expressed as preset abrasive volume +.>
Figure SMS_19
、/>
Figure SMS_9
、/>
Figure SMS_12
Expressed as the amount of manufactured abrasive, the quality of abrasive, and other factors affecting the volume of abrasive, respectively.
The calculation formula of the grinding tool quality evaluation coefficient is as follows:
Figure SMS_21
wherein->
Figure SMS_22
Expressed as a grinding tool quality assessment coefficient->
Figure SMS_23
Expressed as an index of the efficiency of critical parts of the grinding tool, +.>
Figure SMS_24
Expressed as an index of the abrasive article production impact.
The method comprises the following steps:
Figure SMS_25
the three-dimensional model part supervision of the grinding tool is specifically as follows:
obtaining key part efficiency index of target enterprise grinding tool three-dimensional model
Figure SMS_26
The efficiency index of the key parts of the grinding tool is combined with the preset efficiency index of the key parts of the grinding tool>
Figure SMS_27
For comparison, if->
Figure SMS_28
The method is characterized in that the working efficiency of the grinding tool of the target enterprise is abnormal, detail optimization is performed immediately through modeling software, and the three-dimensional model of the grinding tool in an abnormal state is numbered and early-warning displayed.
The concrete assessment mode of the grinding tool quality assessment is as follows:
acquiring grinding tool quality evaluation coefficients of target enterprise grinding tool three-dimensional model
Figure SMS_29
And a preset grinding tool quality evaluation coefficient
Figure SMS_30
For comparison, if->
Figure SMS_31
And if so, indicating that the grinding tool quality of the three-dimensional model of the target enterprise is abnormal, immediately numbering and displaying the abnormal model, sending the result to the enterprise terminal, and modifying the corresponding drawing by a designer, otherwise, indicating that the grinding tool quality state of the three-dimensional model of the target enterprise is normal.
The three-dimensional model safety supervision of the grinding tool is specifically as follows:
and acquiring a three-dimensional model and design information of the target enterprise grinder, storing the three-dimensional model and the design information in an enterprise database, and encrypting data through an RSA algorithm in a model data transmission process.
The invention has the technical effects and advantages that:
1. the invention provides a grinding tool three-dimensional model construction method based on grinding tool design, which comprises the steps of constructing a three-dimensional model of a grinding tool by utilizing computer software, setting observation points, collecting appointed parameter data of a three-dimensional model of a target enterprise grinding tool, preprocessing the parameter data to obtain an efficiency index of key parts of the grinding tool and a production influence index of the grinding tool, further analyzing to obtain a grinding tool quality evaluation coefficient of the three-dimensional model of the target enterprise grinding tool, comparing the grinding tool quality evaluation coefficient with a preset grinding tool quality evaluation coefficient to obtain corresponding treatment measures, so that a quantitative evaluation mechanism is carried out on the grinding tool by the three-dimensional model of the grinding tool, the production cost of an enterprise manufacturing model is reduced, the design decision is facilitated, and the product development process of the enterprise is promoted;
2. according to the invention, the grinding tool key part efficiency index of the three-dimensional model of the target enterprise grinding tool is obtained, the model with abnormal working efficiency of the target enterprise grinding tool is obtained through comparison and analysis, detail optimization is immediately carried out through modeling software, and the three-dimensional model of the grinding tool in an abnormal state is numbered and early-warning displayed, so that the complex process of manually manufacturing the model is simplified, meanwhile, algorithm encryption is used in the process of model data transmission, the safety is improved, and the risk of leakage of an enterprise grinding tool design draft is avoided.
Drawings
FIG. 1 is a schematic diagram of a system connection according to the present invention.
Detailed Description
The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.
Referring to fig. 1, the invention provides a method for constructing a three-dimensional model of a grinding tool based on a grinding tool design, which comprises the steps of three-dimensional model construction of the grinding tool, three-dimensional model information acquisition of the grinding tool, three-dimensional model information processing of the grinding tool, grinding tool quality analysis, three-dimensional model part supervision, grinding tool quality assessment and grinding tool three-dimensional model safety supervision.
The three-dimensional model construction of grinding apparatus is connected with three-dimensional model information acquisition of grinding apparatus, three-dimensional model information acquisition of grinding apparatus is connected with three-dimensional model information processing of grinding apparatus, three-dimensional model information processing of grinding apparatus is connected with quality analysis of grinding apparatus and three-dimensional model part supervision of grinding apparatus, quality analysis of grinding apparatus is connected with quality assessment of grinding apparatus, quality assessment of grinding apparatus is connected with three-dimensional model safety supervision of grinding apparatus.
The three-dimensional model of the grinding tool is constructed to obtain a design drawing of the grinding tool of a target enterprise, the design drawing of the grinding tool is led into a network terminal, and the three-dimensional model of the grinding tool is synthesized by computer software and sequentially recorded as 1 and 2 … … n.
In one possible design, the three-dimensional model of the abrasive article is constructed specifically as follows:
obtaining a grinding tool design drawing of a target enterprise, importing the drawing into computer modeling software to generate a three-dimensional model of the grinding tool, and optimizing the generated three-dimensional model, wherein the three-dimensional model comprises the steps of noise reduction, smooth surface, hole filling, hole removal, superposition removal and operation, and is sequentially recorded as 1 n and 2 n … … n.
Wherein the terminal is a computer.
The grinding tool three-dimensional model information acquisition is used for setting observation points, acquiring the number of parts, the number of key parts, the number of grinding tool manufacturing, the amount of manufacturing grinding tools, the quality of grinding tools and the volume of the grinding tools of a target enterprise, and transmitting data to the grinding tool three-dimensional model information processing.
In one possible design, the specific acquisition mode of the three-dimensional model information acquisition of the grinding tool is as follows:
setting observation points for the three-dimensional model of the target enterprise grinding tool, and collecting the number of parts, the number of key parts, the number of grinding tool manufacturing, the amount of grinding tool manufacturing, the quality of grinding tools and the volume of grinding tools of the three-dimensional model of the target enterprise, wherein the numbers of the amount of grinding tools, the quality of grinding tools and the volume of grinding tools are respectively pl, pg, zg, zm, zf and pz, and the amount of grinding tools manufactured, the quality of grinding tools and the volume of grinding tools are calculated according to a design drawing and the amount of parts of the three-dimensional model.
The grinding tool three-dimensional model information processing is used for receiving data information transmitted by the grinding tool three-dimensional model information acquisition, calculating the key part efficiency index of the grinding tool according to the number of parts, the number of key parts and the manufacturing number of the grinding tool, calculating the production influence index of the grinding tool according to the amount of the grinding tool, the quality of the grinding tool and the volume of the grinding tool, and transmitting the data to the quality analysis of the grinding tool.
In one possible design, the grinding tool key part efficiency index is calculated by the following formula:
Figure SMS_32
*/>
Figure SMS_33
+/>
Figure SMS_34
*/>
Figure SMS_35
wherein->
Figure SMS_36
Expressed as an efficiency index of key parts of the grinding tool, pl expressed as the number of parts, pg expressed as the number of key parts, zg expressed as the number of grinding tool manufacture, e expressed as a natural constant,/>
Figure SMS_37
、/>
Figure SMS_38
Expressed as the number of parts, and the number of abrasive articles made, respectively.
The calculation formula of the grinding tool production influence index is as follows:
Figure SMS_39
+/>
Figure SMS_45
+/>
Figure SMS_47
+/>
Figure SMS_41
wherein->
Figure SMS_44
Expressed as a grinding tool production influence index, zm is expressed as the amount of grinding tool to be manufactured, < >>
Figure SMS_48
Representing the preset amount of the grinding tool to be manufactured, +.>
Figure SMS_50
Expressed as the mass of the abrasive article,
Figure SMS_42
expressed as preset abrasive mass, +.>
Figure SMS_46
Expressed as abrasive volume>
Figure SMS_49
Expressed as preset abrasive volume +.>
Figure SMS_51
、/>
Figure SMS_40
、/>
Figure SMS_43
Expressed as the amount of manufactured abrasive, the quality of abrasive, and other factors affecting the volume of abrasive, respectively.
The grinding tool quality analysis is used for receiving data information transmitted by the grinding tool three-dimensional model information processing, calculating to obtain a grinding tool quality evaluation coefficient through the grinding tool key part efficiency index and the grinding tool production influence index, and transmitting the data to the grinding tool three-dimensional model part supervision and the grinding tool quality evaluation.
In one possible design, the grinding tool quality assessment coefficient is calculated by the following formula:
Figure SMS_52
wherein->
Figure SMS_53
Expressed as a grinding tool quality assessment coefficient->
Figure SMS_54
Expressed as an index of the efficiency of critical parts of the grinding tool, +.>
Figure SMS_55
Expressed as an index of the abrasive article production impact.
The method comprises the following steps:
Figure SMS_56
the grinding tool three-dimensional model part supervision is used for receiving data information transmitted by grinding tool three-dimensional model information processing, comparing the grinding tool key part efficiency index with a preset grinding tool key part efficiency index, carrying out detail processing on the three-dimensional model according to the result, and carrying out numbering early warning display on the grinding tool three-dimensional model in an abnormal state.
In one possible design, the three-dimensional model part of the grinding tool is supervised specifically as follows:
obtaining key part efficiency index of target enterprise grinding tool three-dimensional model
Figure SMS_57
The efficiency index of the key parts of the grinding tool is combined with the preset efficiency index of the key parts of the grinding tool>
Figure SMS_58
For comparison, if->
Figure SMS_59
The method is characterized in that the working efficiency of the grinding tool of the target enterprise is abnormal, detail optimization is performed immediately through modeling software, and the three-dimensional model of the grinding tool in an abnormal state is numbered and early-warning displayed.
The grinding tool quality evaluation is used for acquiring a grinding tool quality evaluation coefficient of the three-dimensional model of the target enterprise grinding tool, comparing the grinding tool quality evaluation coefficient with a preset grinding tool quality evaluation coefficient, if the grinding tool quality evaluation coefficient is smaller than a preset value, indicating that the grinding tool quality of the three-dimensional model of the target enterprise grinding tool is abnormal, immediately numbering and displaying the abnormal model, sending the result to an enterprise terminal, and modifying a corresponding drawing by a designer.
In one possible design, the specific evaluation mode of the grinding tool quality evaluation is as follows:
acquiring grinding tool quality evaluation coefficients of target enterprise grinding tool three-dimensional model
Figure SMS_60
And a preset grinding tool quality evaluation coefficient
Figure SMS_61
For comparison, if->
Figure SMS_62
Indicating that the grinding tool quality of the three-dimensional model of the target enterprise is abnormal, immediately numbering and displaying the abnormal model, and sending the result to the enterprise terminalAnd (3) carrying out corresponding drawing modification by a designer, otherwise, indicating that the grinding tool quality state of the three-dimensional model of the grinding tool of the target enterprise is normal.
The grinding tool three-dimensional model safety supervision is used for storing a target enterprise grinding tool three-dimensional model and a design drawing, and meanwhile data encryption is carried out through an RSA algorithm in the data transmission process.
In one possible design, the three-dimensional model safety supervision of the grinding tool is specifically:
and acquiring a three-dimensional model and design information of the target enterprise grinder, storing the three-dimensional model and the design information in an enterprise database, and encrypting data through an RSA algorithm in a model data transmission process.
In this embodiment, it needs to be specifically explained that, by using computer software to construct a three-dimensional model of the grinding tool, setting observation points, collecting the number of parts, the number of key parts, the number of grinding tool manufacturing, the amount of grinding tool manufacturing, the quality of the grinding tool and the volume of the grinding tool of the target enterprise grinding tool three-dimensional model, preprocessing parameter data to obtain an efficiency index of key parts of the grinding tool and an impact index of grinding tool production, further analyzing to obtain a grinding tool quality evaluation coefficient of the target enterprise grinding tool three-dimensional model, comparing with the preset grinding tool quality evaluation coefficient to obtain corresponding processing measures, thereby realizing a quantifiable evaluation mechanism of the grinding tool through the three-dimensional model of the grinding tool, reducing the production cost of the manufacturing model of the enterprise, facilitating design decision, promoting the product development process of the enterprise, and simultaneously using algorithm encryption in the process of model data transmission, improving safety and avoiding the risk of leakage of design manuscript of the enterprise grinding tool.
Finally: the foregoing description of the preferred embodiments of the invention is not intended to limit the invention to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and principles of the invention are intended to be included within the scope of the invention.

Claims (9)

1. The method for constructing the three-dimensional model of the grinding tool based on the design of the grinding tool is characterized by comprising the following steps of:
step S01: constructing a three-dimensional model of the grinding tool: specifically, a grinding tool design drawing of a target enterprise is obtained, the grinding tool design drawing is imported into a network terminal, a three-dimensional model of the grinding tool is synthesized by using computer software, and the three-dimensional model is sequentially recorded as 1 and 2 … … n;
step S02: and (3) acquiring information of a three-dimensional model of the grinding tool: the method specifically comprises the steps of setting observation points, and collecting the number of parts, the number of key parts, the number of grinding tool manufacturing, the amount of grinding tool manufacturing, the quality of the grinding tool and the volume of the grinding tool of a target enterprise grinding tool three-dimensional model;
step S03: and (3) processing information of the three-dimensional model of the grinding tool: the method comprises the steps of receiving data information transmitted by three-dimensional model information acquisition of a grinding tool, calculating the key part efficiency index of the grinding tool according to the number of parts, the number of key parts and the manufacturing number of the grinding tool, and calculating the manufacturing amount, the quality and the volume of the grinding tool to obtain the production influence index of the grinding tool;
step S04: grinding tool mass analysis: receiving data information transmitted by the processing of the three-dimensional model information of the grinding tool, and calculating to obtain a grinding tool quality evaluation coefficient through the efficiency index of key parts of the grinding tool and the production influence index of the grinding tool;
step S05: monitoring three-dimensional model parts of grinding tools: the method comprises the steps of receiving data information transmitted by the information processing of the three-dimensional model of the grinding tool, comparing the efficiency index of the key part of the grinding tool with the preset efficiency index of the key part of the grinding tool, carrying out detail processing of the three-dimensional model according to the result, and carrying out numbering early warning display on the three-dimensional model of the grinding tool in an abnormal state;
step S06: grinding tool quality evaluation: the method comprises the steps of obtaining a grinding tool quality evaluation coefficient of a target enterprise grinding tool three-dimensional model, comparing the grinding tool quality evaluation coefficient with a preset grinding tool quality evaluation coefficient, if the grinding tool quality evaluation coefficient is smaller than a preset value, indicating that the grinding tool quality of the target enterprise grinding tool three-dimensional model is abnormal, immediately numbering and displaying the abnormal model, sending a result to an enterprise terminal, and modifying a corresponding drawing by a designer;
step S07: safety supervision of three-dimensional model of grinding tool: the method is characterized in that a three-dimensional model and a design drawing of a target enterprise grinding tool are stored, and meanwhile data encryption is carried out through an RSA algorithm in the data transmission process.
2. The method for constructing a three-dimensional model of an abrasive tool based on an abrasive tool design according to claim 1, wherein: the three-dimensional model of the grinding tool is constructed specifically as follows:
obtaining a grinding tool design drawing of a target enterprise, importing the drawing into computer modeling software to generate a three-dimensional model of the grinding tool, and optimizing the generated three-dimensional model, wherein the three-dimensional model comprises the steps of noise reduction, smooth surface, hole filling, hole removal, superposition removal and operation, and is sequentially recorded as 1 n and 2 n … … n.
3. The method for constructing a three-dimensional model of an abrasive tool based on an abrasive tool design according to claim 1, wherein: the specific acquisition mode of the three-dimensional model information acquisition of the grinding tool is as follows:
and setting observation points on the three-dimensional model of the target enterprise grinding tool, and collecting the number of parts, the number of key parts, the number of grinding tool manufacturing, the amount of grinding tool manufacturing, the quality of the grinding tool and the volume of the grinding tool of the target enterprise grinding tool, wherein the numbers are pl, pg, zg, zm, zf and pz respectively.
4. The method for constructing a three-dimensional model of an abrasive tool based on an abrasive tool design according to claim 1, wherein: the calculation formula of the efficiency index of the key parts of the grinding tool is as follows:
Figure QLYQS_1
*/>
Figure QLYQS_2
+/>
Figure QLYQS_3
*/>
Figure QLYQS_4
wherein->
Figure QLYQS_5
Expressed as an efficiency index of critical parts of the grinding tool,pl is the number of parts, pg is the number of key parts, zg is the number of grinding tools, e is a natural constant,>
Figure QLYQS_6
、/>
Figure QLYQS_7
expressed as the number of parts, and the number of abrasive articles made, respectively.
5. The method for constructing a three-dimensional model of an abrasive tool based on an abrasive tool design according to claim 1, wherein: the calculation formula of the grinding tool production influence index is as follows:
Figure QLYQS_9
+/>
Figure QLYQS_12
+/>
Figure QLYQS_17
+/>
Figure QLYQS_10
wherein->
Figure QLYQS_15
Expressed as a grinding tool production influence index, zm is expressed as the amount of grinding tool to be manufactured, < >>
Figure QLYQS_16
Representing the preset amount of the grinding tool to be manufactured, +.>
Figure QLYQS_19
Expressed as abrasive article mass>
Figure QLYQS_11
Expressed as preset abrasive mass, +.>
Figure QLYQS_14
Expressed as abrasive volume>
Figure QLYQS_18
Expressed as preset abrasive volume +.>
Figure QLYQS_20
、/>
Figure QLYQS_8
、/>
Figure QLYQS_13
Expressed as the amount of manufactured abrasive, the quality of abrasive, and other factors affecting the volume of abrasive, respectively.
6. The method for constructing a three-dimensional model of an abrasive tool based on an abrasive tool design according to claim 1, wherein: the calculation formula of the grinding tool quality evaluation coefficient is as follows:
Figure QLYQS_21
wherein->
Figure QLYQS_22
Expressed as a grinding tool quality assessment coefficient->
Figure QLYQS_23
Expressed as an index of the efficiency of critical parts of the grinding tool, +.>
Figure QLYQS_24
Expressed as an abrasive article production impact index;
the method comprises the following steps:
Figure QLYQS_25
7. the method for constructing a three-dimensional model of an abrasive tool based on an abrasive tool design according to claim 1, wherein: the three-dimensional model part supervision of the grinding tool is specifically as follows:
obtaining key part efficiency index of target enterprise grinding tool three-dimensional model
Figure QLYQS_26
The efficiency index of the key parts of the grinding tool is combined with the preset efficiency index of the key parts of the grinding tool>
Figure QLYQS_27
For comparison, if->
Figure QLYQS_28
The method is characterized in that the working efficiency of the grinding tool of the target enterprise is abnormal, detail optimization is performed immediately through modeling software, and the three-dimensional model of the grinding tool in an abnormal state is numbered and early-warning displayed.
8. The method for constructing a three-dimensional model of an abrasive tool based on an abrasive tool design according to claim 1, wherein: the concrete assessment mode of the grinding tool quality assessment is as follows:
acquiring grinding tool quality evaluation coefficients of target enterprise grinding tool three-dimensional model
Figure QLYQS_29
And a preset grinding tool quality evaluation coefficient +.>
Figure QLYQS_30
For comparison, if->
Figure QLYQS_31
And if so, indicating that the grinding tool quality of the three-dimensional model of the target enterprise is abnormal, immediately numbering and displaying the abnormal model, sending the result to the enterprise terminal, and modifying the corresponding drawing by a designer, otherwise, indicating that the grinding tool quality state of the three-dimensional model of the target enterprise is normal.
9. The method for constructing a three-dimensional model of an abrasive tool based on an abrasive tool design according to claim 1, wherein: the three-dimensional model safety supervision of the grinding tool is specifically as follows:
and acquiring a three-dimensional model and design information of the target enterprise grinder, storing the three-dimensional model and the design information in an enterprise database, and encrypting data through an RSA algorithm in a model data transmission process.
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