CN113344669A - Method, system and readable storage medium for purchasing customized parts - Google Patents

Abstract

The invention discloses a method, a system and a readable storage medium for purchasing a customized part, which comprise the following steps: receiving geometric data of a target part sent by a first client, wherein the geometric data is obtained by analyzing a three-dimensional model of the target part after the first client obtains the three-dimensional model; determining rendering parameters of a commodity UI (user interface) corresponding to the target part according to the geometric data; sending the rendering parameters to the second client, wherein after receiving the rendering parameters, the second client renders the commodity UI interface corresponding to the target part according to the rendering parameters, and displays the rendered commodity UI interface; and receiving an order instruction of the target part sent by the second client, and generating order information of the target part according to the order instruction, wherein the order instruction is triggered based on the rendered commodity UI. Through the self-service purchase of the customized part, the purchase efficiency of the customized part is improved.

Description

Method, system and readable storage medium for purchasing customized parts

Technical Field

The invention relates to the technical field of machining, in particular to a method and a system for purchasing a customized part and a readable storage medium.

Background

With the development of the mechanical die industry, parts required by enterprises are more and more complicated, and the demand for customizing parts is higher and higher. However, in the existing customized part purchasing scheme, a demand side is required to send a three-dimensional model drawing of a part to a purchasing staff of a company, the purchasing staff sends the three-dimensional model drawing to different suppliers to quote, the suppliers manually measure and calculate prices based on the three-dimensional model drawing and feed back a quoted price sheet to the purchasing staff, then the purchasing staff compares the quoted prices of the multiple suppliers to determine a final supplier and sends a purchasing order sheet to the supplier, and then the supplier creates an internal order sheet to start ordering and producing after receiving the purchasing order sheet. Therefore, the whole purchasing process of the customized part not only needs the participation and walking of multiple persons of the supply and demand parties, and is very time-consuming, but also is easy to cause quotation errors due to part drawing files and manual measurement errors in the process, or delay of the time of placing a quotation due to unsmooth personnel communication.

Thus, the conventional purchase scheme of the customized parts has the problem of low purchase efficiency.

Disclosure of Invention

The invention mainly aims to provide a method and a system for purchasing a customized part and a readable storage medium, aiming at improving the purchasing efficiency of the customized part.

In order to achieve the above object, the present invention provides a method for purchasing a customized part, which is applied to a server, and comprises the following steps:

receiving geometric data of a target part sent by a first client, wherein the geometric data is obtained by analyzing a three-dimensional model of the target part after the first client obtains the three-dimensional model;

determining rendering parameters of a commodity UI (user interface) corresponding to the target part according to the geometric data;

sending the rendering parameters to the second client, wherein after receiving the rendering parameters, the second client renders the commodity UI interface corresponding to the target part according to the rendering parameters, and displays the rendered commodity UI interface;

and receiving an order instruction of the target part sent by the second client, and generating order information of the target part according to the order instruction, wherein the order instruction is triggered based on the rendered commodity UI.

Optionally, before the step of sending the rendering parameters to the second client, the method further includes:

acquiring identification information of the target part, and storing the identification information and the rendering parameters in a correlated manner;

the step of sending the rendering parameters to the second client comprises:

when a commodity UI (user interface) request sent by the second client is received, determining the identification information corresponding to the commodity UI request;

and acquiring the rendering parameters associated with the identification information, and sending the rendering parameters to the second client.

Optionally, the step of determining rendering parameters of the commodity UI interface corresponding to the target part according to the geometric data includes:

determining delivery cycle and price information of the target part according to the geometric data;

determining the rendering parameters according to the delivery period and the price information.

Optionally, the step of determining delivery cycle and price information of the target part according to the geometric data comprises:

determining the material cost and the processing difficulty coefficient of the target part according to the geometric data;

and determining delivery cycle and price information of the target part according to the material cost and the processing difficulty coefficient.

Optionally, the step of receiving the geometric data of the target part sent by the first client further includes:

and receiving the three-dimensional model screenshot of the target part sent by the first client.

Optionally, after the step of generating the order information of the target part according to the order instruction, the method further includes:

receiving the processing drawing file of the target part sent by the second terminal;

and storing the order information and the processing drawing file in a correlation mode.

In addition, in order to achieve the above object, the present invention further provides a method for purchasing a customized part, which is applied to a client, and the method for purchasing a customized part includes:

acquiring a three-dimensional model of a target part;

acquiring geometric data of the target part based on the three-dimensional model of the target part, and sending the geometric data to a server connected with the client;

receiving rendering parameters of the commodity UI interface fed back by the server based on the geometric data;

correspondingly rendering the commodity UI interface of the target part according to the rendering parameters of the commodity UI interface, and displaying the rendered commodity UI interface of the target part;

receiving an order instruction of the target part triggered based on the commodity UI interface, and sending the order instruction to the server side so that the server side can generate order information of the target part according to the order instruction.

Optionally, the step of obtaining a three-dimensional model of the target part includes:

and extracting a three-dimensional model corresponding to a preset name from the part drawing file to serve as the three-dimensional model of the target part.

In addition, in order to achieve the above object, the present invention further provides a purchasing system for a customized part, including a memory, a processor, and a purchasing program for a customized part stored on and executable on the processor, wherein the processor implements the steps of the purchasing method for a customized part as described above when executing the purchasing program for a customized part.

In addition, to achieve the above object, the present invention further provides a readable storage medium having a customized part purchasing program stored thereon, the customized part purchasing program implementing the steps of the customized part purchasing method as described above when executed by a processor.

In the embodiment of the invention, after the first client side obtains the geometric data of the target part according to the three-dimensional model of the target part, the geometric data of the target part can be sent to the server side. Therefore, the server side can determine rendering parameters of the commodity UI interface corresponding to the target part according to the geometric data of the target part by receiving the geometric data of the target part sent by the first client side and send the rendering parameters to the second client side, then the second client side renders the commodity UI interface corresponding to the target part according to the received rendering parameters for displaying, and an order instruction of the target part can be triggered based on the displayed commodity UI interface. And then, after receiving the order instruction of the target part sent by the second client, the server side can generate the order information of the target part according to the order instruction to perform customized production. Therefore, automatic rendering of the commodity UI interface of the customized part can be achieved based on the geometric data of the target part uploaded by the first client, self-service purchase of the customized part can be achieved based on the commodity UI interface, the delay of the time for placing the order of the quotation due to manual quotation errors or due to unsmooth personnel communication can be avoided, and the purchase efficiency of the customized part can be improved.

Drawings

FIG. 1 is a schematic diagram of a system for purchasing a customized part in a hardware operating environment according to an embodiment of the present invention;

FIG. 2 is a schematic flow chart diagram of a first embodiment of a method for purchasing a customized part according to the present invention;

FIG. 3 is a schematic flow chart diagram illustrating a second embodiment of a customized part purchasing method according to the present invention;

FIG. 4 is a flow chart illustrating a third embodiment of the method for purchasing a customized part according to the present invention.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The main solution of the invention is: receiving geometric data of a target part sent by a first client, wherein the geometric data is obtained by analyzing a three-dimensional model of the target part after the first client obtains the three-dimensional model; determining rendering parameters of a commodity UI (user interface) corresponding to the target part according to the geometric data; sending the rendering parameters to the second client, wherein after receiving the rendering parameters, the second client renders the commodity UI interface corresponding to the target part according to the rendering parameters, and displays the rendered commodity UI interface; and receiving an order instruction of the target part sent by the second client, and generating order information of the target part according to the order instruction, wherein the order instruction is triggered based on the rendered commodity UI.

At present, the whole purchasing process of the customized parts not only needs the participation and walking of multiple persons of both sides, which is time-consuming, but also is easy to cause quotation errors due to part drawing files and manual measurement errors, or delay of the time of placing a quotation due to unsmooth communication of personnel. The present invention thus proposes the above solution, improving the purchase efficiency of customized parts.

Referring to fig. 1, fig. 1 is a schematic diagram of a system for purchasing a customized part in a hardware operating environment according to an embodiment of the present invention.

As shown in fig. 1, the customized parts purchasing system may include: a communication bus 1002, a processor 1001, such as a CPU, a user interface 1003, a network interface 1004, and a memory 1005. Wherein a communication bus 1002 is used to enable connective communication between these components. The user interface 1003 may include a Display screen (Display), an input unit such as a Keyboard (Keyboard), and the optional user interface 1003 may also include a standard wired interface, a wireless interface. The network interface 1004 may optionally include a standard wired interface, a wireless interface (e.g., WI-FI interface). The memory 1005 may be a high-speed RAM memory or a non-volatile memory (e.g., a magnetic disk memory). The memory 1005 may alternatively be a storage device separate from the processor 1001.

Those skilled in the art will appreciate that the customized parts purchasing system configuration shown in FIG. 1 does not constitute a limitation on the customized parts purchasing system, and may include more or fewer components than shown, or some components in combination, or a different arrangement of components.

In the customized parts purchasing system shown in fig. 1, the network interface 1004 is mainly used for connecting with a background server and performing data communication with the background server; the user interface 1003 is mainly used for connecting a client (user side) and performing data communication with the client; and processor 1001 may be configured to invoke the purchase procedure for the customized part stored in memory 1005 and perform the associated steps in the following embodiments of the method for purchasing a customized part.

Referring to fig. 2, fig. 2 is a flowchart of a first embodiment of a method for purchasing a customized part according to the present invention. In this embodiment, the method for purchasing a customized part includes the following steps:

step S10: receiving geometric data of a target part sent by a first client, wherein the geometric data is obtained by analyzing a three-dimensional model of the target part after the first client obtains the three-dimensional model;

it should be noted that the purchasing method of the customized parts proposed in this embodiment is applied to the server. The service end is a server or terminal equipment which is oriented to a part customization service provider, can automatically generate rendering parameters of a commodity UI (user interface) of a customized part according to geometric data of the customized part, and can generate order information of the customized part according to an order instruction triggered based on the commodity UI; the first client refers to a terminal device capable of automatically analyzing geometric data of a target part included in a part drawing; the target part refers to a customized part that the first client needs to customize.

When the user has the part customization requirement, the part drawing file can be imported into the first client. And when the first client receives the part drawing file, the three-dimensional model of each part in the part drawing file can be automatically identified. However, not all of the identified three-dimensional models are three-dimensional models of the target part that require customization. Therefore, before acquiring the geometric data of the target part, the first client screens out the three-dimensional model of the target part from the part drawing file.

The manner of obtaining the three-dimensional model of the target part by the first client may be: and extracting a three-dimensional model corresponding to a preset name from the part drawing file to serve as the three-dimensional model of the target part.

Specifically, before the three-dimensional model of the target part is obtained, a target part database may be established in advance, and a preset name of the target part to be customized may be stored in the target part database in advance. The preset name may be a part name or a part number of a target part to be customized, which is written when the customized part database is set up. In addition, the model name of each part stored in advance can be acquired from the entity attribute of each three-dimensional model in the part drawing. Then, the preset name in the database may be compared with the model name obtained from the entity attribute, and the three-dimensional model with the model name consistent with the preset name in the part drawing file is used as the three-dimensional model of the target part, that is, the three-dimensional model corresponding to the preset name in the part drawing file is used as the three-dimensional model of the target part.

The manner of obtaining the three-dimensional model of the target part by the first client may also be: and manually selecting the three-dimensional model from the part drawing file as the three-dimensional model of the target part. At this time, the three-dimensional model of each part and/or the model name of the three-dimensional model recognized from the part drawing file may be displayed in the form of a list, a grid, or the like in the first client, so that the user may select the corresponding three-dimensional model as the three-dimensional model of the target part. For example, after the three-dimensional model corresponding to the preset name is taken as the three-dimensional model of the target part, the corresponding three-dimensional model may be selected from three-dimensional models other than the three-dimensional model of the preset name as the three-dimensional model of the target part.

After the three-dimensional model of the target part is obtained, the first client can obtain the geometric data of the target part according to the three-dimensional model of the target part. Specifically, after the client scans the three-dimensional model of the target part, a preset analysis model is called to analyze the three-dimensional model of the target part, so as to obtain the geometric data of the target part. The specific analysis process may be: the method comprises the steps of firstly determining a processing surface and processing contents of a target part, and then determining geometric data such as size data, the number and the size data of the processing surface, the number of the processing contents, the processing direction and the size data of the target part. The processing surface of the target part is the surface which needs to be processed for processing the part blank into the target part, and the more the number of the processing surfaces of the target part is, the more complex the part processing is; the processing content of the target part is holes, grooves or other processing contents which need to be formed in the process of processing the part blank into the target part, and the more the processing content of the target part is, the more complex the part processing is; the size data of the target part is the overall size data of the target part and can comprise length data, width data, height data and the like, the shapes of the target parts are different, the size data of the corresponding target parts are different, and the size data is not specifically limited; the size data of the processing content at least comprises size data of holes and grooves to be processed by the target part, the size data of the holes can comprise the diameters and the depths of the holes, and the size data of the grooves can comprise the groove volumes and the groove areas; the machining direction information is the machining direction in which the machining content is located, and the more the machining direction of the part is, the more complicated the machining of the part is.

Optionally, the first client may further obtain one or more items of data of the bevel area, the plane area, and the curved surface area of the target part, and use the obtained bevel area, plane area, and curved surface area as the geometric data of the target part.

Because the enterprise generally needs the quotation document for approval and signature when purchasing. Price lists of different parts are usually marked by part numbers, and effective distinguishing of the different parts cannot be achieved. Therefore, in an embodiment, when the first client obtains the geometric data of the target part according to the three-dimensional model of the target part, the first client may also obtain a three-dimensional model screenshot of the target part according to the three-dimensional model of the target part. At this time, a three-dimensional model screenshot of the target part may be taken as one of the geometric data of the target part. Here, the three-dimensional model screenshot of the target part may be at least one sectional view in an arbitrary direction of the three-dimensional model of the target part or at least one sectional screenshot in an arbitrary direction of the three-dimensional model of the target part in order to distinguish the quotation of the target part. That is, the acquired three-dimensional model screenshot may be a single three-dimensional model screenshot or may be multiple three-dimensional model screenshots.

After the first client acquires the geometric data of the target part, the geometric data of the target part and the target part can be associated and then sent to a server connected with the first client, so that the server can generate rendering parameters of a commodity UI. The identification information of the target part may include number information, name information, supplier information, and a three-dimensional model screenshot of the target part.

Step S20: determining rendering parameters of a commodity UI (user interface) corresponding to the target part according to the geometric data;

after the server receives the geometric data of the target part sent by the first client, rendering parameters of a commodity UI (user interface) corresponding to the target part can be determined according to the geometric data, so that the commodity UI of the target part can be generated according to the rendering parameters, and self-service purchase of the target part can be realized based on the commodity UI. The method for determining the rendering parameters of the commodity UI interface corresponding to the target part specifically may be: the method comprises the steps of firstly determining which parameters can be included in rendering parameters corresponding to a commodity UI interface, and then determining the rendering parameters corresponding to the commodity UI interface according to geometric data of a target part, so that the conditions that the rendering parameters are incomplete or the rendering parameters are wrong and the like are avoided, and further self-service purchase of the target part is influenced.

It should be noted that the rendering parameter of the product UI interface corresponding to the target part refers to the relevant information of the target part that needs to be displayed on the product UI interface at the second client. In this embodiment, the rendering parameters of the UI interface of the commodity corresponding to the target part may include price information (including actual price information and discount information calculated according to the geometric data), delivery cycle, identification information, two-dimensional code information, quotation, purchase link, page sharing information, and the like of the target part.

When determining the rendering parameters of the commodity UI corresponding to the target part according to the geometric data of the target part, the price information and the delivery cycle of the target part need to be determined according to the geometric data of the target part. The service end is preset with a calculation formula of price information of the target part (such as a processing cost calculation formula, a material cost calculation formula, a fitting cost calculation formula, a price discount calculation formula and the like) and a calculation formula of delivery cycle of the target part. When the server side receives the geometric data sent by the first client side, a calculation formula of the price information of the target part and a calculation formula of the delivery cycle of the target part can be directly called, and the price information and the delivery cycle of the target part are calculated according to the geometric data of the target part. After the price information and the delivery cycle of the target part are determined, the two-dimensional code information, the purchase link and the page sharing information of the target part can be generated according to the price information, the delivery cycle and the identification information of the target part. At this time, the identification information, price information, delivery cycle, two-dimensional code information, purchase link and page sharing information of the target part can be used as the rendering parameters of the commodity UI interface corresponding to the target part.

However, in order to facilitate the client to obtain the quotation of the target part to perform purchase approval on the target part, the server may further use the three-dimensional model screenshot of the target part and the identification information, price information, delivery cycle, two-dimensional code information, purchase link, and page sharing information of the target part as rendering parameters of the UI interface of the commodity corresponding to the target part.

Optionally, the service end can also generate a quotation of the target part according to the three-dimensional model screenshot, the price information, the delivery cycle and the identification information of the target part, and then the quotation, the identification information, the price information, the delivery cycle, the two-dimensional code information, the purchase link and the page sharing information of the target part are jointly used as rendering parameters of a commodity UI interface corresponding to the target part, so that the purchase efficiency of the client is improved.

Optionally, after determining the rendering parameter of the commodity UI interface corresponding to the target part, the server may further obtain the rendering parameter of the commodity UI interface corresponding to the target part, associate the rendering parameter of the commodity UI interface corresponding to the target part with the identification information of the target part, and store the associated rendering parameter in the rendering parameter database of the server. Therefore, when the commodity UI interface corresponding to the target part needs to be displayed at the second client next time, the rendering parameters of the commodity UI interface corresponding to the target part can be quickly found according to the identification information of the target part, the geometric data of the target does not need to be obtained again to generate the rendering parameters of the target part, the display speed of the commodity UI interface corresponding to the target part can be increased, and the purchase efficiency of the target part can be increased.

Step S30: sending the rendering parameters to the second client, wherein after receiving the rendering parameters, the second client renders the commodity UI interface corresponding to the target part according to the rendering parameters, and displays the rendered commodity UI interface;

after the rendering parameters of the commodity UI interface corresponding to the target part are determined, the server side sends the determined rendering parameters to the second client side, and therefore after the second client side receives the rendering parameters, the commodity UI interface corresponding to the target part can be rendered according to the rendering parameters, and the rendered commodity UI interface is displayed. Further, the content displayed by the item UI interface may include: identification information, price information, delivery cycle, two-dimension code information, purchase link information, page sharing information (convenient for forwarding to a purchasing colleague for purchasing), a quotation and the like of the target part. In this way, since the rendering parameters may include the two-dimensional code information of the target part, the purchase link of the target part, and the like, the user may implement self-service purchase of the target part in a manner of scanning a code or opening a web page link, and the like, based on the commodity UI interface corresponding to the target part displayed by the second client, without participating in multiple parties.

Wherein, if a plurality of parts needing customization exist, the displayed price information can be the total price of the plurality of parts or the unit price of different parts. And the quotation displayed on the commodity UI interface can be the quotation generated by the second client according to the corresponding rendering parameters, or the quotation of the target part sent to the second client by the server. The displayed content of the quotation can comprise price information, delivery cycle, identification information (such as part number), three-dimensional model screenshot, payment method, contact method, commodity two-dimensional code (which is convenient for customers to scan codes to check commodities by mobile phones and forward and share the same to purchase colleagues for ordering), and the like of the target part. In addition, when the second client side renders the commodity UI interface corresponding to the target part according to the rendering parameters, because the second client side is preset with the page rendering strategy of the target part, after the rendering parameters corresponding to the target part are received, the commodity UI interface corresponding to the target part can be rendered according to the page rendering strategy. The page rendering policy preset by the second client may include display positions and display modes corresponding to different rendering parameters, and may be set individually according to user requirements, which is not specifically limited herein.

In an embodiment, before sending the rendering parameter to the second client, after the identification information of the target part and the rendering parameter of the target part are stored in an associated manner, when the rendering parameter of the target part is sent to the second client, the rendering parameter of the target part can be accurately and quickly found according to the identification information. Specifically, the user may trigger a commodity UI interface request corresponding to the target part on the second client, and after receiving the commodity UI interface request at the server, may obtain identification information corresponding to the commodity UI interface request from request information corresponding to the commodity UI interface request. And obtaining the rendering parameter matched with the identification information from a pre-stored rendering parameter database, and taking the rendering parameter as the rendering parameter corresponding to the commodity UI interface request, namely, taking the rendering parameter as the rendering parameter of the commodity UI interface corresponding to the target part. And then, the rendering parameters are sent to a second client, and a commodity UI corresponding to the target part is rendered and generated by the second client and displayed, so that the user can purchase the target part based on the displayed commodity UI.

It should be noted that the second client refers to a terminal device that can be communicatively connected with the server and has a page rendering and displaying function. The first client and the second client may be the same terminal or different terminals. When the first client side and the second client side are the same, the client side can analyze and customize the geometric data of the part according to the three-dimensional model, and can render the commodity UI interface corresponding to the target part according to the rendering parameters sent by the server side and display the rendered commodity UI interface.

In addition, it is to be noted that in some other embodiments, after the commodity UI interface corresponding to the target part is rendered according to the rendering parameter by the server, the rendered commodity UI interface may be directly sent to the second client, and the commodity UI interface is displayed by the second client. Therefore, the loading time of the second client side in displaying the commodity UI interface can be reduced, and the waiting time of the user is further reduced.

Step S40: and receiving an order instruction of the target part sent by the second client, and generating order information of the target part according to the order instruction, wherein the order instruction is triggered based on the rendered commodity UI.

In order to implement self-service purchase of the customized part to reduce manual participation, in this embodiment, the user may directly trigger an order instruction of the target part on the commodity UI interface displayed by the second client, and send the order instruction to the server. And after receiving the order instruction, the server can generate order information of the target part according to the order instruction so as to be used by a supplier for material ordering production according to the purchase order. When the user purchases the target part based on the commodity UI displayed by the second client, the settlement can be directly carried out on a single commodity, or a plurality of commodities can be added into the shopping cart for settlement together. When the user accesses the commodity UI interface, the system already acquires the login information of the user, and when the user selects and purchases the customized parts, the selected and purchased customized parts can be directly stored in the shopping cart corresponding to the login information for batch settlement. In addition, when the selected customized parts are settled, payment settlement can be carried out according to a payment mode corresponding to the user login information stored in the server, such as cash. For example, if the customer settlement method is monthly, no payment is required for placing the order. In addition, after the order is created, the supplier can update the order state in real time, and the order state can be conveniently checked by the demand side in real time.

Since the server only acquires the geometric data of the three-dimensional model for quotation, but the geometric data of the three-dimensional model cannot be used for realizing the precise processing of the target part, in order to facilitate a supplier to precisely process the target part, before the material ordering production is performed based on the purchase order, a processing drawing file (a complete drawing file of the three-dimensional model) of the target part needs to be acquired so as to perform the processing treatment of the target part based on the processing drawing file. The step of obtaining the processing drawing file of the target part can be that when the first client sends the geometric data to the server, the geometric data is related to the geometric data and sent to the server; or when the second client sends the purchase instruction based on the commodity UI interface, the second client uploads the processing drawing file of the target part based on the accessory uploading function on the commodity UI interface, and then the purchase instruction and the processing drawing file are associated and sent to the server. In an embodiment, after the purchase order of the target part is generated according to the purchase instruction, the second client uploads the machining drawing of the target part based on the accessory uploading function on the commodity UI interface, and then associates the machining drawing of the target part with the purchase order and sends the associated machining drawing to the server. At this time, the supplier of the target part can look up the processing drawing file of the target part for processing based on the associated purchase order, and then feed back the processing information of the target part to the second client based on the associated purchase order, so as to realize the accurate processing and real-time feedback of the target part. The time node for sending the processing drawing file by the second client is not specifically limited, and the processing drawing file can be sent according to actual application requirements, and only needs to be sent before the server user carries out material ordering production.

In the embodiment, the geometric data of the target part sent by the first client is received, the rendering parameter of the commodity UI interface corresponding to the target part is determined according to the geometric data of the target part, and then the rendering parameter is sent to the second client, so that after the second client receives the rendering parameter, the commodity UI interface corresponding to the target part can be rendered according to the rendering parameter, and the rendered commodity UI interface is displayed. Therefore, automatic quotation of the customized part can be achieved based on the geometric data of the target part uploaded by the first client side, self-service purchase can be achieved based on the commodity UI displayed by the second client side, participation of multiple personnel of both sides of a process is not needed, delay of quotation ordering time caused by errors of manual quotation or unsmooth communication of the personnel can be avoided, and purchase efficiency of the customized part is improved.

Based on the above embodiment, a second embodiment of the purchasing method of the customized part of the present invention is proposed. Referring to fig. 3, in the present embodiment, the method for purchasing a customized part includes the following steps:

step S10: receiving geometric data of a target part sent by a first client, wherein the geometric data is obtained by analyzing a three-dimensional model of the target part after the first client obtains the three-dimensional model;

step S201: determining delivery cycle and price information of the target part according to the geometric data;

step S202: determining a rendering parameter of a commodity UI (user interface) corresponding to the target part according to the delivery period and the price information;

step S30: sending the rendering parameters to the second client, wherein after receiving the rendering parameters, the second client renders the commodity UI interface corresponding to the target part according to the rendering parameters, and displays the rendered commodity UI interface;

step S40: and receiving an order instruction of the target part sent by the second client, and generating order information of the target part according to the order instruction, wherein the order instruction is triggered based on the rendered commodity UI.

Since the user focuses on the delivery cycle and the price information when purchasing the customized part, in this embodiment, it is preferable to determine the rendering parameter of the UI interface of the product corresponding to the target part according to the delivery cycle and the price information. Therefore, after receiving the geometric data of the target part sent by the first client, the server needs to determine the delivery cycle of the target part according to the geometric data, and determine the price information of the target part according to the geometric data, so as to determine the rendering parameters corresponding to the target part according to the delivery cycle and the price information of the target part and send the rendering parameters to the second client for page rendering, so that based on the rendered commodity UI interface displayed by the second client, a user can visually see the delivery cycle, the price information and the like of the target part, thereby facilitating the user to quickly match the purchase demand and further accelerating the purchase efficiency.

In one embodiment, the delivery cycle of the target part according to the geometric data of the target part may be determined by: the method comprises the steps of firstly determining the material cost and the processing difficulty coefficient of a target part according to geometric data of the target part, and then determining the delivery cycle and the price information of the target part according to the determined material cost and the processing difficulty coefficient. The price information of the target part can be determined according to the material cost and the processing difficulty coefficient of the target part; the delivery cycle of the target part can be determined according to the processing difficulty coefficient of the target part. And the material cost of the target part can be determined according to the size data of the target part. The processing materials of different materials have different unit prices, the corresponding material costs are different, and the same target part can be customized through different processing materials; the processing difficulty coefficient of the target part depends on the processing content of the target part, such as a processing surface to be processed on the target part and non-planar processing contents such as a hole and a groove to be processed. The processing difficulty coefficients of the holes with different diameters and different processing precisions are different, the processing difficulty coefficients corresponding to the grooves with different sizes and different processing precisions are different, and the processing difficulty coefficients corresponding to the processing surfaces with different areas and different processing precisions are also different.

In a specific processing procedure, on one hand, the corresponding relationship between different processing contents and the processing difficulty coefficient may be pre-established, for example, the corresponding relationship between holes with different diameters and different processing accuracies and the processing difficulty coefficient, the corresponding relationship between grooves with different sizes and different processing accuracies and the processing difficulty coefficient, and the corresponding relationship between processing surfaces with different areas and different processing accuracies and the processing difficulty coefficient may be pre-established. In addition, the corresponding relation between the processing difficulty coefficient and the delivery cycle of the target part and the corresponding relation between the processing difficulty coefficient and the processing cost can be established in advance. The correspondence relationship here may be a mapping relationship or a functional relationship. Since the corresponding relationships adopted by different suppliers are different, the specific corresponding relationship is not specifically limited herein. Based on the pre-established corresponding relation, the delivery cycle and the processing cost of the target part can be determined by table lookup, function calculation and the like. Wherein, the higher the processing difficulty coefficient, the longer the delivery cycle, and the higher the processing cost. On the other hand, the material cost of the target part can be obtained by multiplying the size information by the quantity information and then multiplying the size information by the unit price information according to the size information and the quantity information corresponding to different materials on the target part and the unit price information corresponding to different materials which are preset. Then, the material cost and the machining cost of the target part are added to obtain the price information of the target part. Since the delivery cycle and the price information corresponding to different suppliers are calculated in different manners, they are only listed here and are not limited specifically.

Alternatively, since the target part is machined by using different machining materials and different machining methods, the price information and delivery cycle of the target part calculated correspondingly may be different. Therefore, when the first client specifies the machining material and the machining method of the target part when transmitting the geometry data of the target part to the server, the machining cost, the material cost, and the delivery cycle of the target part can be calculated in accordance with the specified machining material and machining method. If the first client does not specify the processing material and the processing mode of the target part, the price information and the delivery cycle of the target part can be calculated according to the preset processing material and the processing mode which are available for processing the target part. Here, the preset processing material may be a single processing material or a plurality of processing materials; the preset processing mode can be a single processing mode or a plurality of processing modes. Since the type of machining material and the type of machining method that can be used for different target parts may vary, the specific machining method and the machining material are not particularly limited.

When a plurality of machining modes and/or a plurality of machining materials exist, price information and delivery cycle of the target part can be calculated according to different machining modes and/or different machining materials respectively. At this time, since there are a plurality of calculated price information and a plurality of calculated delivery cycles, the plurality of calculated price information and the plurality of calculated delivery cycles can be all used as rendering parameters to be sent to the second client to render the commodity UI interface corresponding to the target part, so that the user can select from the commodity UI interface. Optionally, the calculated multiple price information and multiple delivery cycles may also be fed back to the first client, after the first client performs selection and confirmation, the confirmed price information and delivery cycle are used as final price information and delivery cycle of the target part, and then the confirmed price information and delivery cycle are used as rendering parameters of a commodity UI interface corresponding to the target part and sent to the second client for rendering of the commodity UI interface, so that the user can quickly place orders according to the rendered commodity UI interface without further selection.

In the embodiment, the delivery cycle and the price information of the target part are determined through the geometric data of the target part, the rendering parameters of the commodity UI interface corresponding to the target part are determined according to the delivery cycle and the price information of the target part, and the rendering parameters are sent to the second client side, so that the second client side renders the commodity UI interface corresponding to the target part according to the rendering parameters and displays the commodity UI interface, a user can quickly match with the purchase demand based on the commodity UI interface, and purchase of the target part is achieved.

A third embodiment of the purchasing method of the customized part of the invention is proposed based on the above-described embodiments. Referring to fig. 4, in the present embodiment, the method for purchasing a customized part includes the following steps:

step S11: acquiring a three-dimensional model of a target part;

step S21: acquiring geometric data of the target part based on the three-dimensional model of the target part, and sending the geometric data to a server connected with the client;

step S31: receiving rendering parameters of the commodity UI interface fed back by the server based on the geometric data;

step S41: correspondingly rendering the commodity UI interface of the target part according to the rendering parameters of the commodity UI interface, and displaying the rendered commodity UI interface of the target part;

step S51: receiving an order instruction of the target part triggered based on the commodity UI interface, and sending the order instruction to the server side so that the server side can generate order information of the target part according to the order instruction.

It should be noted that the purchase method of the customized part proposed in this embodiment is applied to the client. Here, the client is a terminal device which can be used for acquiring a three-dimensional model of a target part, acquiring geometric data of the target part according to the three-dimensional model of the target part, rendering a commodity UI interface of the target part with rendering parameters of the commodity UI interface for display, and receiving an order instruction of the target part triggered based on the commodity UI interface and sending the order instruction to a server connected to the client.

In this embodiment, the client may obtain a part drawing for customizing the part, where the part drawing may be created by the user in real time at the client, or stored in advance to the client after being created by the user, or transmitted to the client through a wireless transmission or communication interface after being pre-made by the user. After the client side obtains the part drawing file, the three-dimensional model of each part in the part drawing file can be identified by calling the preset model. However, not all of the identified three-dimensional models are three-dimensional models of the target part that require customization. Therefore, before acquiring the geometric data of the target part, the client screens out the three-dimensional model of the target part from the part drawing.

The method for the client to obtain the three-dimensional model of the target part may be as follows: and extracting a three-dimensional model corresponding to a preset name from the part drawing file to serve as the three-dimensional model of the target part.

Specifically, before the three-dimensional model of the target part is obtained, a target part database may be established in advance, and a preset name of the target part to be customized may be stored in the target part database in advance. The preset name may be a part name or a part number of a target part to be customized, which is written when the customized part database is set up. In addition, the model name of each part stored in advance can be acquired from the entity attribute of each three-dimensional model in the part drawing. Then, the preset name in the database may be compared with the model name obtained from the entity attribute, and the three-dimensional model with the model name consistent with the preset name in the part drawing file is used as the three-dimensional model of the target part, that is, the three-dimensional model corresponding to the preset name in the part drawing file is used as the three-dimensional model of the target part.

The method for the client to obtain the three-dimensional model of the target part can also be as follows: and manually selecting the three-dimensional model from the part drawing file as the three-dimensional model of the target part. At this time, the three-dimensional models of the parts and/or the model names of the three-dimensional models identified from the part drawing file may be displayed in the form of a list, a grid, or the like in the client, so that the user may select the corresponding three-dimensional model as the three-dimensional model of the target part. For example, after the three-dimensional model corresponding to the preset name is taken as the three-dimensional model of the target part, the corresponding three-dimensional model may be selected from three-dimensional models other than the three-dimensional model of the preset name as the three-dimensional model of the target part.

After the three-dimensional model of the target part is obtained, the client can obtain the geometric data of the target part according to the three-dimensional model of the target part. Specifically, after the client scans the three-dimensional model of the target part, a preset analysis model is called to analyze the three-dimensional model of the target part, so as to obtain the geometric data of the target part. The specific analysis process may be: the method comprises the steps of firstly determining a processing surface and processing contents of a target part, and then determining geometric data such as size data, the number and the size data of the processing surface, the number of the processing contents, the processing direction and the size data of the target part. The processing surface of the target part is the surface which needs to be processed for processing the part blank into the target part, and the more the number of the processing surfaces of the target part is, the more complex the part processing is; the processing content of the target part is holes, grooves or other processing contents which need to be formed in the process of processing the part blank into the target part, and the more the processing content of the target part is, the more complex the part processing is; the size data of the target part is the overall size data of the target part and can comprise length data, width data, height data and the like, the shapes of the target parts are different, the size data of the corresponding target parts are different, and the size data is not specifically limited; the size data of the processing content at least comprises size data of holes and grooves to be processed by the target part, the size data of the holes can comprise the diameters and the depths of the holes, and the size data of the grooves can comprise the groove volumes and the groove areas; the machining direction information is the machining direction in which the machining content is located, and the more the machining direction of the part is, the more complicated the machining of the part is.

Optionally, the client may further obtain one or more items of data of the bevel area, the plane area, and the curved surface area of the target part, and use the obtained bevel area, plane area, and curved surface area as the geometric data of the target part.

In addition, when the enterprise purchases, the quotation document is generally required to be used for approval and signature. Price lists of different parts are usually marked by part numbers, and effective distinguishing of the different parts cannot be achieved. Therefore, in an embodiment, when the client acquires the geometric data of the target part according to the three-dimensional model of the target part, the client may also acquire a three-dimensional model screenshot of the target part according to the three-dimensional model of the target part. At this time, a three-dimensional model screenshot of the target part may be taken as one of the geometric data of the target part. Here, the screenshot of the three-dimensional model of the target part may be at least one screenshot of an arbitrary direction of the three-dimensional model of the target part in order to distinguish the quotation of the target part. That is, the acquired three-dimensional model screenshot may be a single three-dimensional model screenshot or may be multiple three-dimensional model screenshots.

After the client acquires the geometric data of the target part, the geometric data of the target part and the target part can be associated and then sent to a server connected with the client, so that the geometric data of the target part and the target part can be used when the server generates rendering parameters of a commodity UI (user interface). The identification information of the target part may include number information, name information, supplier information, and a three-dimensional model screenshot of the target part.

And after receiving the rendering parameters, the client can render the commodity UI corresponding to the target part according to the rendering parameters and display the rendered commodity UI. Further, the content displayed by the item UI interface may include: identification information, price information, delivery cycle, two-dimension code information, purchase link information, page sharing information (convenient for forwarding to a purchasing colleague for purchasing), a quotation and the like of the target part.

In one embodiment, a user may trigger a commodity UI interface request corresponding to a target part on a client, where the commodity UI interface request includes identification information of the target part. Then, the rendering parameters associated with the identification information can be requested to the server side according to the identification information as the rendering parameters of the commodity UI interface corresponding to the target part. After the client receives the rendering parameters of the target part, the commodity UI interface corresponding to the target part can be obtained through rendering according to the rendering parameters of the target part and displayed, so that a user can purchase the target part based on the commodity UI interface corresponding to the target part.

The user can directly trigger the order instruction of the target part on the commodity UI displayed by the client side and send the order instruction to the server side. When the user purchases the target part based on the commodity UI displayed by the second client, the settlement can be directly carried out on a single commodity, or a plurality of commodities can be added into the shopping cart for settlement together. When the user accesses the commodity UI interface, the system already acquires the login information of the user, and when the user selects and purchases the customized parts, the selected and purchased customized parts can be directly stored in the shopping cart corresponding to the login information for batch settlement. In addition, when the selected customized parts are settled, payment settlement can be carried out according to a payment mode corresponding to the user login information stored in the server, such as cash. For example, if the customer settlement method is monthly, no payment is required for placing the order. In addition, after the order is created, the supplier can update the order state in real time, and the order state can be conveniently checked by the demand side in real time.

Optionally, when sending the geometric data of the target part to the server, the client may specify a machining material and a machining mode that are required to be used for machining the target part; or when the rendering parameters provided by the server include a plurality of price information and a plurality of delivery cycles, the commodity UI interface corresponding to the target part includes a plurality of rendering interfaces corresponding to different price information and delivery cycles or the different price information and the delivery cycles are simultaneously displayed on the same rendering interface. At this time, at least one of price information and delivery cycle can be selected by the client for customized production.

In the embodiment, the three-dimensional model of the target part is obtained, the geometric data of the target part is obtained according to the three-dimensional model of the target part, the geometric data is sent to the server connected with the client, the rendering parameters of the commodity UI interface fed back by the server based on the geometric data are received, the commodity UI interface of the target part is correspondingly rendered according to the rendering parameters of the quotation interface, the rendered commodity UI interface of the target part is displayed, the order instruction of the target part triggered based on the commodity UI interface is received, and the order instruction is sent to the server so that the server can generate the order information of the target part according to the order instruction. Therefore, the order of the target part is automatically placed based on the commodity UI displayed by the client, so that the situation that multiple persons of a supplier and a demand supplier participate in the order placement only through a complex flow is avoided, the order placement flow can be saved, and the purchase efficiency of the customized part can be improved.

In addition, an embodiment of the present invention further provides a readable storage medium, where the readable storage medium stores a purchase program of a customized part, and the purchase program of the customized part, when executed by a processor, implements the steps of the purchase method of the customized part as described above.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or system. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or system that comprises the element.

The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner. Based on such understanding, the technical solution of the present invention may be embodied in the form of a software product, which is stored in a storage medium (e.g., ROM/RAM, magnetic disk, optical disk) as described above and includes instructions for enabling a terminal device (e.g., a mobile phone, a computer, a server, a television, or a network device) to execute the method according to the embodiments of the present invention.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. A method for purchasing a customized part is applied to a server, the server is connected with a first client, and the server is connected with a second client, and the method for purchasing the customized part comprises the following steps:

receiving geometric data of a target part sent by a first client, wherein the geometric data is obtained by analyzing a three-dimensional model of the target part after the first client obtains the three-dimensional model;

determining rendering parameters of a commodity UI (user interface) corresponding to the target part according to the geometric data;

sending the rendering parameters to the second client, wherein after receiving the rendering parameters, the second client renders the commodity UI interface corresponding to the target part according to the rendering parameters, and displays the rendered commodity UI interface;

and receiving an order instruction of the target part sent by the second client, and generating order information of the target part according to the order instruction, wherein the order instruction is triggered based on the rendered commodity UI.

2. The method of purchasing a customized part according to claim 1, wherein said step of sending said rendering parameters to said second client is preceded by the step of:

acquiring identification information of the target part, and storing the identification information and the rendering parameters in a correlated manner;

the step of sending the rendering parameters to the second client comprises:

when a commodity UI (user interface) request sent by the second client is received, determining the identification information corresponding to the commodity UI request;

and acquiring the rendering parameters associated with the identification information, and sending the rendering parameters to the second client.

3. The method for purchasing a customized part according to claim 1, wherein the step of determining rendering parameters of a commodity UI (user interface) corresponding to the target part according to the geometric data comprises the following steps:

determining delivery cycle and price information of the target part according to the geometric data;

determining the rendering parameters according to the delivery period and the price information.

4. The method of purchasing a customized part according to claim 3, wherein said step of determining delivery cycle and price information for said target part based on said geometric data comprises:

determining the material cost and the processing difficulty coefficient of the target part according to the geometric data;

and determining delivery cycle and price information of the target part according to the material cost and the processing difficulty coefficient.

5. The method of purchasing a customized part according to claim 1, wherein said step of receiving geometry data of the target part sent by the first client further comprises:

and receiving the three-dimensional model screenshot of the target part sent by the first client.

6. The method of purchasing a customized part according to claim 1, wherein said step of generating order information for said target part according to said order instruction is followed by further comprising:

receiving the processing drawing file of the target part sent by the second terminal;

and storing the order information and the processing drawing file in a correlation mode.

7. A method for purchasing a customized part, applied to a client, the method comprising the steps of:

acquiring a three-dimensional model of a target part;

acquiring geometric data of the target part based on the three-dimensional model of the target part, and sending the geometric data to a server connected with the client;

receiving rendering parameters of the commodity UI interface fed back by the server based on the geometric data;

correspondingly rendering the commodity UI interface of the target part according to the rendering parameters of the commodity UI interface, and displaying the rendered commodity UI interface of the target part;

receiving an order instruction of the target part triggered based on the commodity UI interface, and sending the order instruction to the server side so that the server side can generate order information of the target part according to the order instruction.

8. The method of purchasing a customized part as recited in claim 7, wherein said step of obtaining a three-dimensional model of the target part comprises:

and extracting a three-dimensional model corresponding to a preset name from the part drawing file to serve as the three-dimensional model of the target part.

9. A customized parts purchasing system, comprising a memory, a processor and a customized parts purchasing program stored on the memory and operable on the processor, wherein the processor executes the customized parts purchasing program to implement the steps of the customized parts purchasing method of any one of claims 1-8.

10. A readable storage medium, having stored thereon a purchase program of a customized part, which when executed by a processor, performs the steps of the purchase method of a customized part according to any one of claims 1-8.

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