CN116227885B - Personalized honeycomb customized service system and method - Google Patents

Abstract

The utility model discloses a personalized honeycomb customized service system and method, belonging to the technical field of honeycomb design, wherein the system comprises: the user interaction module is used for acquiring the honeycomb image information customized by the user; the management platform is used for receiving the honeycomb image information, judging the feasibility of the preview honeycomb pattern, and converting the preview honeycomb pattern into a corresponding frame assembly pattern when judging that the preview honeycomb pattern has the feasibility; transmitting the pattern to frame assembly processing equipment; receiving nesting related information, and issuing the nesting related information according to a corresponding user ID; and the nesting information interaction module is used for interacting nesting related information. The utility model enables consumers to participate in the honeycomb manufacturing process in the early stage of the bee production process, enables the users to know the honeycomb structure more clearly, and greatly improves the user participation degree, thereby improving the user experience.

Description

Personalized honeycomb customized service system and method

Priority application

The present utility model will be the basis of priority for subsequent patent applications including, but not limited to, chinese patent application, PCT application, foreign application based on paris convention.

Technical Field

The invention relates to the technical field of honeycomb, in particular to a method and a system capable of customizing a multi-shape honeycomb.

Background

The honeycomb honey is commonly called as honeycomb, is a honey spleen brewed by bees and covered with wax, is a mature honey composed of two parts of honeycomb and honey, also called as "covering honey", has much higher nutrition and active substances than common honey, contains rich biological enzymes, vitamins and various microelements, has better health care and disease treatment effects, and is a best quality product in honey. In the traditional honey manufacturing process, a honeycomb foundation is fixedly arranged on a rectangular frame in a sheet shape or a plane shape by a bee farmer, and then a piece of honeycomb is arranged in a beehive to nest and inject honey by bees. After the honey is finally obtained, a piece of honeycomb honey is collected by a bee grower, and the honeycomb honey is cut, split-packed and packaged according to the actual demand of a consumer and finally sent to the hand of the consumer. However, this conventional production method faces the following problems:

1) In terms of product marketing, the product is cut and split-packed into a packaging bottle or a packaging can made of plastic or glass, so that the product form finally presented to a consumer is single, the consumer cannot be attracted, the identification degree of the product in a plurality of bee products cannot be increased, and the expansion of honey sales is not facilitated. In order to open the way for honey, there is therefore an increasing demand for new forms of honey products.

2) From the consumer's perspective, the entire process from honeycomb manufacture to last take of the honey product is not engaged in any link, nor is the information of any link in the honey brewing process known. That is, the entire production process of the honey product is almost isolated from the consumer. However, in today's trending society, this undoubtedly greatly reduces the consumer's sense of experience and engagement. On the other hand, in the present society, as a mode of combining practice experience and teaching is more and more popular, more and more schools can let students or parents take children to a farm or a product production place to perform field observation, and even participate in a certain procedure. However, due to safety concerns, even if consumers or children are looking in the field, they are usually only able to observe outside the hive or by the queen bee farmer taking out the frame, but the outside observations alone do not actually make a deep sense or learn about the honeycomb structure and life habits etc.

In view of this, how to enable consumers to participate in new forms and viable honeycomb structural designs, and to realize customization of honeycomb/honeycomb honey, so that the product forms are enriched, and at the same time, improvement of user experience is a current urgent need to be solved.

Disclosure of Invention

The invention aims to provide a personalized honeycomb customized service method which can facilitate users to participate in the honeycomb honey production process so as to customize a personalized new-form honeycomb structure, thereby increasing user experience.

In order to solve the technical problems, the invention adopts the following technical scheme: a personalized cellular customization service system, comprising: a template library for providing a user with a honeycomb template; the honeycomb template comprises a base profile for forming an outer profile of a honeycomb frame, and a base unit for filling the base profile; the user interaction module is used for acquiring the honeycomb image information customized by the user and binding the honeycomb image information with the user ID of the user; the honeycomb image information includes: the cell type, and a two-dimensional preview cell pattern generated based on the cell template specified by the user; the management platform is used for receiving the honeycomb image information, judging the feasibility of the preview honeycomb pattern, converting the preview honeycomb pattern into a corresponding frame assembly pattern when judging that the preview honeycomb pattern has the feasibility, and then sending the frame assembly pattern to processing equipment so as to trigger the processing equipment to process the corresponding frame assembly; receiving the processing completion information of the frame component uploaded by the processing equipment, informing a beekeeper to splice the frame component and then putting the spliced frame component into a beehive for nesting; receiving nesting related information, and issuing the nesting related information according to a corresponding user ID; and the nesting information interaction module is used for interacting nesting related information. Specifically, the preview honeycomb pattern can be automatically adjusted based on the preset feasibility determining standard by a machine learning mode.

As an improvement, the management platform comprises: the image conversion unit is used for searching a corresponding three-dimensional honeycomb template in the template library based on the preview honeycomb pattern, and if the corresponding three-dimensional honeycomb template is found, the triggering feasibility judgment unit judges that the preview honeycomb pattern has feasibility, and the corresponding frame assembly pattern is found in the template library according to the three-dimensional honeycomb template; if not, converting the preview honeycomb pattern into a three-dimensional honeycomb model to trigger a feasibility judging unit to judge the feasibility of the preview honeycomb pattern based on the three-dimensional honeycomb model; and when the preview honeycomb pattern is judged to be feasible, generating a corresponding frame assembly pattern based on the three-dimensional honeycomb model corresponding to the preview honeycomb pattern; the feasibility judging unit is used for judging whether the distance between each basic unit on the outer mold in the three-dimensional honeycomb structure and the corresponding inner wall in the simulation beehive is larger than a preset size threshold value or not after the three-dimensional honeycomb model/the three-dimensional honeycomb template is placed in the preset simulation beehive in the middle when the honeycomb type is identified as the three-dimensional honeycomb structure, and whether the included angle between the basic units extending along the axis direction on the three-dimensional honeycomb frame body in the three-dimensional honeycomb structure and the included angle between the basic units extending along the axis direction on the outer mold in the three-dimensional honeycomb structure are larger than an angle threshold value or not; and gaps between the basic units on the three-dimensional frame body and the corresponding basic units on the outer mold meet a preset gap threshold range; if yes, judging that the preview honeycomb pattern has feasibility; or, when the honeycomb type is identified as a radial honeycomb structure, determining whether a minimum distance between an edge of each base outline in the radial honeycomb structure and a corresponding inner wall in a preset simulated beehive is greater than a preset size threshold or not, and whether a distance between two adjacent base outlines in the radial honeycomb structure is greater than a preset distance threshold or not, if so, determining that the preview honeycomb pattern has feasibility, and triggering the image conversion unit to generate a corresponding frame assembly pattern based on the three-dimensional honeycomb model corresponding to the preview honeycomb pattern.

As an improvement, the feasibility judging unit is further used for judging whether the included angle between the basic units extending along the axial direction on the internal mold is larger than an angle threshold value or not when the upright honeycomb structure is identified to be provided with the internal mold; and gaps between the basic units on the three-dimensional frame body and the corresponding basic units on the inner mold meet a preset gap threshold range; if yes, judging that the preview honeycomb pattern has feasibility.

As an improvement, when the upright honeycomb structure is identified to have a bottom surface, whether the included angle between the bottom surface and the surrounding basic units is larger than the preset angle threshold value is judged, and if yes, the preview honeycomb pattern is judged to have feasibility.

As an improvement, when the upright honeycomb structure is identified to have a bottom surface and a top surface, judging whether an included angle between the bottom surface and the surrounding base units is larger than the preset angle threshold, judging whether the ratio of the surface area of the bottom surface to the surface area of the top surface is larger than the preset ratio threshold, and if yes, judging that the preview honeycomb pattern has feasibility.

As an improvement, the user interaction module comprises: the visual design unit is used for generating a 2D preview honeycomb pattern according to the honeycomb parameters input by a user; the honeycomb parameters include the honeycomb type, the honeycomb templates specified by the user in the template library, and the manner in which the honeycomb templates are assembled. Of course, the honeycomb shape, the honeycomb size, etc. may be further specified.

As an improvement, the feasibility determining unit is further configured to automatically adjust the preview honeycomb pattern based on a preset feasibility determining standard and regenerate the preview honeycomb pattern having feasibility when it is determined that the preview honeycomb pattern has no feasibility.

As an improvement, the management platform further comprises: the storage unit is used for storing the user ID information uploaded by the user interaction module and the honeycomb image information; storing nesting related information uploaded by the nesting information interaction module; and/or an instruction compiling unit for compiling the frame assembly pattern into a 3D printing command or CNC cutting parameter instruction.

As an improvement, the management platform comprises: the honey amount prediction unit is used for calculating the quantity of the comb foundations paved on the frame according to the frame assembly pattern, the three-dimensional honeycomb model or the three-dimensional honeycomb template, and predicting the honey amount of the corresponding honeycomb of the frame assembly according to the honey production historical data of the comb foundations and the quantity of the comb foundations; and/or a scheme design unit, configured to plan the required honeycomb type and number according to the order list of the user and historical order data, where the order list includes honey amount, and the historical order data includes the honeycomb type, size and number used in the history for confirmation by the user. Namely, according to the automatic planning scheme of the historical goods ordering amount of the long-term cooperative user, the time of the user is greatly saved, and the efficiency is improved.

As an improvement, the management platform further comprises: the processing management unit is used for selecting processing equipment and issuing a frame assembly pattern; and receiving processing completion information uploaded by the processing equipment, wherein the processing completion information comprises processing equipment identity information, processing equipment position information, frame assembly serial numbers, user ID information and logistics information.

As an improvement, the temperature and humidity control subsystem is arranged in the beehive; the temperature and humidity control subsystem comprises a controller, a temperature sensor, a humidity sensor, a non-light heater and a ventilation fan.

The invention also provides a personalized honeycomb customized service method, which comprises the following steps: acquiring customized honeycomb image information of a user, and binding the honeycomb image information with a user ID of the user; the honeycomb image information includes a honeycomb type, and a two-dimensional preview honeycomb pattern generated based on each honeycomb template specified by the user in a template library; the honeycomb template comprises a basic contour for forming an outer contour of a honeycomb and a basic unit for filling the basic contour; searching a corresponding three-dimensional honeycomb template in a template library based on the preview honeycomb pattern, if so, judging that the preview honeycomb pattern has feasibility, and searching the corresponding frame assembly pattern in the template library according to the three-dimensional honeycomb template; if not, generating the three-dimensional honeycomb model based on the preview honeycomb pattern, and judging the feasibility of the preview honeycomb pattern by combining with a preset feasibility judging standard; when the preview honeycomb pattern is judged to have feasibility, generating a corresponding frame assembly pattern based on the three-dimensional honeycomb model for the preview honeycomb pattern with feasibility, and sending the frame assembly pattern to processing equipment so as to trigger the processing equipment to process a corresponding frame assembly, and informing a beekeeper to put the frame assembly into a beehive for nesting; after the frame component is placed into a beehive for nesting, the nesting related information is uploaded; and corresponding nesting related information is issued according to the user ID. Of course, if the three-dimensional honeycomb template is matched, the user can also change various parameters thereof, such as the size, the base unit, etc., so that the feasibility determination is required in the same manner as described above after the change.

As an improvement, the step of judging the feasibility of the preview honeycomb pattern includes: identifying a honeycomb type; if the honeycomb type is a three-dimensional honeycomb structure, judging whether the distance between each basic unit on the outer mold in the three-dimensional honeycomb structure and the corresponding inner wall in the simulated beehive is larger than a preset size threshold value or not when the three-dimensional honeycomb model/the three-dimensional honeycomb template is placed in the preset simulated beehive in the middle, and whether the included angles between the basic units extending along the axial direction on the three-dimensional honeycomb frame body in the three-dimensional honeycomb structure and the included angles between the basic units extending along the axial direction on the outer mold in the three-dimensional honeycomb structure are larger than an angle threshold value or not; and gaps between the basic units on the three-dimensional frame body and the corresponding basic units on the outer mold meet a preset gap threshold range; if yes, judging that the preview honeycomb pattern has feasibility; or if the honeycomb type is a radial honeycomb structure, judging whether the minimum distance between the edge of each piece of basic outline in the radial honeycomb structure and the corresponding inner wall in the simulation beehive is larger than a preset size threshold value or not after the three-dimensional honeycomb model/the three-dimensional honeycomb template is placed in the preset simulation beehive in the middle, and judging whether the distance between two adjacent pieces of basic outlines in the radial honeycomb structure is larger than a preset distance threshold value or not if yes, wherein the preview honeycomb pattern has feasibility.

As an improvement, the step of judging the feasibility of the preview honeycomb pattern further includes: if the upright honeycomb structure is provided with an inner die, judging whether an included angle between foundation units extending along the axial direction of each foundation unit on the inner die is larger than an angle threshold value or not; and gaps between the basic units on the three-dimensional frame body and the corresponding basic units on the inner mold meet a preset gap threshold range; if yes, judging that the preview honeycomb pattern has feasibility.

As an improvement, the step of judging the feasibility of the preview honeycomb pattern further includes: if the upright honeycomb structure is provided with a bottom surface, judging whether an included angle between the bottom surface and the surrounding basic units is larger than the preset angle threshold value; if yes, judging that the preview honeycomb pattern has feasibility.

As an improvement, the step of judging the feasibility of the preview honeycomb pattern further includes: if the upright honeycomb structure is provided with a bottom surface and a top surface, judging whether an included angle between the bottom surface and surrounding basic units is larger than the preset angle threshold, and whether the ratio of the surface area of the bottom surface to the surface area of the top surface is larger than the preset ratio threshold, if so, judging that the preview honeycomb pattern is feasible.

As an improvement, the method further comprises the steps of: and if the preview honeycomb pattern is judged to be not feasible, automatically adjusting the preview honeycomb pattern based on a preset feasibility judgment standard, and regenerating the preview honeycomb pattern with feasibility. For consumers who do not have rich expertise, for example, children are not generally aware of how to adjust, so the system can be automatically adjusted based on preset judgment standards through a machine learning mode, which specifically includes: if the minimum distance between the basic unit on the three-dimensional honeycomb model/the three-dimensional honeycomb template and each edge of the inner periphery of the beehive is smaller than or equal to the preset size threshold, the size of the three-dimensional honeycomb model can be reduced so that the three-dimensional honeycomb model meets the condition; or, adaptively adjusting the inclination angle of the base unit at the minimum pitch position and the peripheral base units thereof so as to satisfy the condition; and/or if the minimum spacing between each frame of the radial structure is less than or equal to the preset spacing threshold, correspondingly, the number of frame frames can be reduced, and the spacing between the rest frame frames can be adaptively adjusted so as to meet the condition; and/or if the included angle between the foundation units extending along the axial direction on the three-dimensional honeycomb frame body in the three-dimensional honeycomb model/the three-dimensional honeycomb template is judged, and/or the included angle between the foundation units extending along the axial direction on the outer mold in the three-dimensional honeycomb structure is smaller than or equal to a preset included angle threshold value, automatically adjusting the inclination of the foundation units at the corresponding positions and the surrounding foundation units so as to meet the condition; and/or if the ratio of the bottom surface area to the top surface area of the three-dimensional frame body in the three-dimensional honeycomb model/the three-dimensional honeycomb template is smaller than or equal to the preset ratio threshold value, increasing the ground surface area or reducing the top surface area. Specifically, if the automatic adjustment is unsuccessful, the user may be fed back to manually adjust or redraw the preview honeycomb pattern.

As an improvement, the frame assembly processing steps include: transmitting processing confirmation information to the idle processing equipment; after confirmation and reply are obtained, the frame component pattern is sent to the processing equipment; processing equipment processes according to the frame component pattern, and after the processing is finished, uploading processing equipment identity information, processing equipment position information, frame component serial numbers, user ID information and logistics information; if the confirmation reply is not obtained, searching for the next idle processing equipment until the confirmation reply is obtained.

As an improvement, the method further comprises the steps of: calculating the number of laid comb foundations according to the frame assembly pattern/the three-dimensional honeycomb model/the three-dimensional honeycomb template; and calculating the honey production amount of the honeycomb corresponding to the frame component according to the honey production historical data of the honeycomb basis and the honeycomb basis number.

As an improvement, the method further comprises the steps of: planning the required honeycomb types and the required honeycomb amounts according to the order list of the user and historical order data, wherein the order list comprises honey amounts, and the historical order data comprises the honeycomb types, the honeycomb sizes and the honeycomb amounts used in the history.

The invention has the advantages that: as described in the background art, the conventional honeycomb adopts a sheet square frame, so in order to enrich the product shape and increase the product identification, the applicant has proposed a concept of a three-dimensional frame nest. Generally, when designing the three-dimensional frame, people most often think of the three-dimensional structure of the wild honeycomb, and the structure is the most suitable for the life habit of bees, therefore, only the structure design of the wild honeycomb is needed. However, on one hand, the structure of the wild honeycomb is complex, the existing technology has certain difficulty in processing the honeycomb with the same structure, and if the wild honeycomb structure is adopted, the so-called personalized customization is avoided; on the other hand, if the wild honeycomb structure is adopted, the design participation degree of the users is greatly reduced, even if the users have no participation possibility (especially children), the natural users cannot participate in the honeycomb design link, and the user experience is greatly reduced.

The invention provides a personalized honeycomb customizing platform, which enables consumers (such as honey buyers, or honeycomb buyers, or practice experimenters) to customize honeycomb structures based on a template library by setting the template library, judges whether the customized frame structures of the consumers accord with the feasibility conditions of the frames, provides possibility for the users to participate in the nesting environment in the honey making process, enables the users to participate in the manufacturing process of the honeycombs in the honey producing process, and can more clearly understand the honeycomb structures, namely greatly improves the participation degree of the users, thereby improving the user experience, and on the other hand, the users can customize the personalized shaped honeycombs in the platform, not only enriches the shapes of honey products, but also greatly increases the recognition degree of the honey products, provides a new path for the integration of urban and rural areas, and helps to increase the income of honeyfarmers.

The honeycomb honey is usually taken together with honey belt nest, and the three-dimensional frame body can be designed into various shapes according to requirements, so that the finally obtained honeycomb honey also forms the same appearance, and a honey product with a new shape is obtained. Compared with the traditional plate-shaped honeycomb honey, the honeycomb honey has the advantages that the honeycomb honey is divided and packaged into the same product form in the packaging bottle, the honeycomb honey has higher identification degree, and meanwhile, consumers can be attracted more, namely, the selling point of the product is increased.

On the other hand, the honeycomb honey is the honeycomb which is eaten together with the honey belt nest, so the finally obtained three-dimensional honeycomb can be directly used as a final product and then subjected to external packing, without cutting, weighing and split charging, the production process flow of the product is simplified, the workload of beekeepers is greatly reduced, and the waiting time for finally reaching the consumer user is shortened.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. Like elements or portions are generally identified by like reference numerals throughout the several figures. In the drawings, elements or portions thereof are not necessarily drawn to scale. It will be apparent to those of ordinary skill in the art that the drawings in the following description are of some embodiments of the invention and that other drawings may be derived from these drawings without inventive faculty.

FIG. 1a is a schematic diagram of a structural framework of the present invention;

FIG. 1b is a functional block diagram of an exemplary embodiment of the present invention;

FIG. 2 is a flow chart of the present invention;

FIG. 3a is a schematic diagram of a preview honeycomb pattern customized using the system of the present invention;

FIG. 3b is a schematic illustration of a three-dimensional frame body in a three-dimensional honeycomb template based on the preview honeycomb pattern of FIG. 3 a;

FIG. 3c is a schematic diagram of a three-dimensional honeycomb template structure of an exemplary embodiment stored in a template library of the present invention;

FIG. 4 is an exploded view of the three-dimensional honeycomb template of FIG. 3 c;

FIG. 5 is a schematic diagram of a three-dimensional honeycomb template of yet another exemplary embodiment stored in a template library of the present invention;

fig. 6 is a schematic view of a three-dimensional honeycomb template (hollowed-out body) according to another exemplary embodiment stored in a template library according to the present invention;

FIG. 7 is a schematic diagram of a three-dimensional honeycomb template of yet another exemplary embodiment stored in a template library of the present invention;

FIG. 8 is a schematic diagram of an exemplary embodiment of a structure of a honeycomb template stored in a template library of the present invention;

fig. 9 is a schematic diagram of a honeycomb template structure of yet another exemplary embodiment stored in a template library of the present invention;

fig. 10 is a schematic view of a three-dimensional honeycomb template structure of still another exemplary embodiment stored in a template library of the present invention;

FIG. 11 is a physical diagram of a customized three-dimensional honeycomb structure obtained based on the platform of the present invention;

Fig. 12 is a schematic illustration of bees nesting and injecting honey in a customized three-dimensional honeycomb structure.

Reference numerals: an outer mold 1, a three-dimensional frame body 2 and a bottom plate 3; 11 flange edges, 12 bases, 13 positioning convex blocks and 14 positioning grooves; 15 internal mold; 31 hollowed-out and 32 positioning convex blocks; 31 hollowed-out and 32 positioning convex blocks; stake sets 21, male frames 22, frame frames 23, twisted honeycomb plates 24; a base profile of a 41 trapezoid; a 42 rectangular base profile; a 51-trapezoid base unit; 52 rectangular base unit.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present application. It will be apparent that the described embodiments are some, but not all, embodiments of the application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application. In this document, suffixes such as "module", "component", or "unit" used to represent elements are used only for facilitating the description of the present application, and have no particular meaning in themselves. Thus, "module," "component," or "unit" may be used in combination. The terms "upper," "lower," "inner," "outer," "front," "rear," "one end," "the other end," and the like herein refer to an orientation or positional relationship based on that shown in the drawings, merely for convenience of description and to simplify the description, and do not denote or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the application. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. The terms "mounted," "configured to," "connected," and the like, herein, are to be construed broadly as, for example, "connected," whether fixedly, detachably, or integrally connected, unless otherwise specifically defined and limited; the two components can be mechanically connected, can be directly connected or can be indirectly connected through an intermediate medium, and can be communicated with each other. The specific meaning of the above terms in the present application will be understood in specific cases by those of ordinary skill in the art. Herein, "and/or" includes any and all combinations of one or more of the associated listed items. Herein, "plurality" means two or more, i.e., it includes two, three, four, five, etc. 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 apparatus 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 apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element. The "frame outer profile" in the present application refers to the external shape of the frame that is presented to the consumer, e.g., vase-like, ring-like, pagoda-like. In general, the outer contours can be represented by a two-dimensional graphic of the front or front view of the frame, and each outer contour can be formed from a plurality of regular geometric shapes or irregular shapes by stacking or stitching, e.g., the outer contour of a vase can be formed from a rectangular or trapezoidal stack or stitching, see FIG. 3a.

The honey and the honeycomb are taken as basic agricultural products, the economic added value is not high, and the income of the beefarmers is low. Meanwhile, along with the continuous development of the urban process, more and more people do not know the process of honeying bees. On one hand, the bee farmers are eagerly required to expand sales, and enrich sales forms; on the other hand, consumers hope to participate in some links in the whole honey nesting process, so that participation and experience are improved, and personalized products can be obtained according to different requirements of the consumers. In order to solve the above technical problems, as shown in fig. 1a and fig. 1b, the present invention provides a personalized honeycomb customized service system, which includes a template library, a user interaction module, a management module, a nesting information interaction module, and a temperature and humidity control subsystem. The modules and subsystems are described one by one.

A template library for providing a user with a honeycomb template; in particular, the honeycomb template comprises a base profile for constituting the outer profile of the honeycomb, and a base unit for filling the base profile. In some embodiments, the base profile refers to various base shapes that form the outer profile of the three-dimensional frame body by stacking or stitching, e.g., regular or irregular geometric shapes such as trapezoids, circles, rectangles, and the like. For example, as shown in fig. 3a, the user obtains a vase-like outer contour by designating a trapezoidal base contour 41 and a rectangular base contour 42 in a template library, and splicing the plurality of base contours. Of course, the stacking or the splicing of various basic shapes can form a vase shape, and can also form the outer contours of ellipse, ring, pagoda shape and the like. In some embodiments, a base unit refers to the smallest unit that fills the base outline, e.g., a base unit or units fill a base. For example: trapezoid, triangle, rectangle, polygon (e.g., pentagon, hexagon), etc. As shown in fig. 3a, the user designates a trapezoidal base unit 51 in the template library for filling for the trapezoidal base outline 41; for rectangular outline 42, rectangular base cells 52 are specified in the template library to fill. Of course, the shape of each base profile may be the same as or different from the shape of the filled base unit. For example, the rectangular outline may also be filled with triangular or trapezoidal base cells. Preferably, one of the base units disposed on the frame corresponds to one of the comb foundations. In other embodiments, the template library is further pre-stored with a two-dimensional honeycomb pattern having a predetermined outer contour, and a corresponding three-dimensional honeycomb template and frame assembly pattern.

The user interaction module is used for acquiring the honeycomb image information customized by the user and binding the honeycomb image information with the user ID of the user; the system comprises a management platform, a nesting platform and a nesting platform, wherein the management platform is used for managing nesting information; specifically, the visual design unit is included. In some embodiments, the cellular image information includes: a honeycomb type (e.g., a stereo honeycomb structure, a radial honeycomb structure), and generating a two-dimensional preview honeycomb pattern of the corresponding frame based on the honeycomb templates specified by the user in the template library.

The visual design unit is used for outputting a 2D preview honeycomb pattern according to the honeycomb parameters input by a user; the honeycomb parameters include the honeycomb type, the honeycomb templates specified by the user in the template library, and the combination of the honeycomb templates. The combination mode is that a user configures the size of each honeycomb template through enlarging or reducing, even attribute editing, and the honeycomb templates are assembled through moving or dragging, rotating and other operations, so that a two-dimensional honeycomb pattern with an outer contour is obtained.

It is contemplated that the user interaction module further comprises a login registration unit for the user to register the ID information and log in. The user registers an ID through the user interaction module so that the user has a unique ID. After registration, the personalized honeycomb of the user can be designed through a visual design unit under the user interaction module. Because honeycombs require bees to nest, the shape cannot be designed to be too complex, otherwise it is not beneficial to shape. Thus, in the present invention, custom shapes are generally easier to implement, such as spheres, rings, flower vase shapes, and the like. Specifically, the system prompts the user to select a particular cell type, and the user first selects the cell type, such as a radial or a solid, in the user interface. Then selecting a specific basic outline in the template library, and forming the selected basic outline into a honeycomb pattern with an outer outline, such as the sphere, the ring, the vase type, etc., and then selecting a corresponding one or more basic units for each outer basic outline to fill (specifically, once the size of the basic outline, the shape and the size of the basic units are determined by a user, the number of basic units required for filling the corresponding basic outline can be automatically calculated, and if the basic outline cannot be completely filled, proper adjustment can be automatically performed).

The visual design unit can generate a 2D image of the honeycomb for reference by a user after receiving the honeycomb parameters. Of course, the user can also perform parameter modification (e.g., height, width, radius, etc.) based on the existing two-dimensional honeycomb pattern templates in the template library (e.g., storing the front view corresponding to the three-dimensional frame body in the three-dimensional honeycomb structure of fig. 3 b-10 as the corresponding two-dimensional honeycomb pattern, or the front view corresponding to the frame in the radial honeycomb structure as the corresponding two-dimensional honeycomb pattern). After the honeycomb image information is determined, the user interaction module uploads the honeycomb image information to the management platform, and meanwhile the honeycomb image information is bound with the user ID information, so that tracking can be facilitated, and consistency can be ensured.

The management platform is preferably a cloud management platform and is used for receiving the honeycomb image information and judging the feasibility of previewing the honeycomb pattern in the honeycomb image information; when the preview honeycomb pattern is judged to have feasibility, converting the preview honeycomb pattern into a corresponding frame assembly pattern, and when the preview honeycomb pattern is judged to not have feasibility, automatically adjusting the preview honeycomb pattern based on a preset feasibility judgment standard, regenerating the preview honeycomb pattern with feasibility, converting the preview honeycomb pattern into the corresponding frame assembly pattern, and then transmitting the frame assembly pattern to processing equipment to trigger the processing equipment to process the corresponding frame assembly; receiving frame component processing completion information uploaded by frame processing equipment, informing a beekeeper to splice the frame components and then placing the spliced frame components into a beehive for nesting; and receiving the nesting related information and issuing the nesting related information according to the corresponding user ID.

Of course, in other embodiments, in order to reduce the system power consumption, before converting to the three-dimensional honeycomb model, whether there is a corresponding three-dimensional honeycomb template (specifically, the three-dimensional honeycomb template may be automatically matched through deep learning) may be first matched in the template library, and if not, the three-dimensional honeycomb model is converted to the three-dimensional model, and the feasibility determination is performed.

Specifically, the management platform further comprises a feasibility judging unit, a storage unit, an image conversion unit, an instruction compiling unit, a processing management unit, a honey amount prediction unit, a scheme design unit and the like.

A feasibility judging unit for judging the feasibility of the preview honeycomb pattern; not any size and shape of the hives can be achieved by honeybee nesting. It is therefore necessary to judge the feasibility first, especially for honeycomb shapes that are fully custom-made by the user (i.e., do not match the corresponding three-dimensional template and frame assembly patterns in the template library), but only have a viable honeycomb structure, where bees enter and nest smoothly and inject honey, as shown in fig. 12. Specifically, the criterion for judging feasibility is: if the honeycomb type is a three-dimensional honeycomb structure, after the three-dimensional honeycomb model/three-dimensional honeycomb template is centrally placed in a preset simulated beehive, the minimum distance between each base unit on the outer mold in the three-dimensional honeycomb structure and the corresponding inner wall in the simulated beehive is larger than a preset size threshold (for example, the distance between each side of the inner periphery of the beehive after the actual honeycomb is centrally placed is larger than 100mm in order to leave a manufacturing space as shown in fig. 11); moreover, for the three-dimensional honeycomb structure, the included angle (30 degrees as shown in fig. 3 b) between the basic units extending along the axial direction on the three-dimensional frame body is met, and the included angle between the basic units extending along the axial direction on the outer mold in the three-dimensional honeycomb structure is larger than an angle threshold; and gaps between the basic units on the three-dimensional frame body and the corresponding basic units on the outer mold meet a preset gap threshold range (2-3 cm).

If the honeycomb type is radial, the following are satisfied: the three-dimensional honeycomb model/the three-dimensional honeycomb template is centrally placed behind a preset simulated beehive, wherein the minimum distance between the edge of each frame and the corresponding inner wall in the simulated beehive is larger than a preset size threshold; it is also desirable that the minimum spacing between each frame be greater than a spacing threshold (3 cm).

Further, if the upright honeycomb structure has an inner mold, the included angle between the foundation units extending along the axial direction of each foundation unit on the inner mold needs to be larger than the angle threshold; and gaps between the basic units on the three-dimensional frame body and the corresponding basic units on the inner mold meet a preset gap threshold range.

Further, if the upright honeycomb structure has a bottom surface, an included angle between the bottom surface and the surrounding base units is greater than a preset angle threshold; if the pillar honeycomb structure has a bottom surface and a top surface, the ratio of the surface area of the bottom surface to the surface area of the top surface is greater than a predetermined ratio threshold (3/4 as shown in fig. 3 b).

Through continuous practice, bees can enter the honeycomb with any shape and structure to nest and inject honey, and for some honeycombs, even if bees enter the honeycomb and inject honey, the honeycomb nesting time is 4-5 months, namely the honeycomb nesting time is greatly prolonged (namely the honeycomb structure does not have feasibility), however, the honeycomb nesting only needs 1-2 weeks. Therefore, when the user customizes the structure, the feasibility of the structure needs to be identified, so that the feasibility of the customized honeycomb structure is ensured.

Of course, if it is determined that the preview honeycomb pattern is not feasible, the preview honeycomb pattern is automatically adjusted based on a preset feasibility determination criterion, and a feasible preview honeycomb pattern is regenerated. For some users with less experience and lack of relevant expertise, the user experience is greatly improved by automatically adjusting the user according to the drawn graph.

The storage unit is used for storing the user ID information uploaded by the user interaction module and the honeycomb image information; and storing nesting related information uploaded by the nesting information interaction module.

And the image conversion unit is used for converting the 2D preview honeycomb pattern into a 3D model so as to trigger the feasibility judgment unit to judge the feasibility of the preview honeycomb pattern based on the three-dimensional honeycomb model, and generating a frame assembly pattern through the 3D model when judging that the preview honeycomb pattern is feasible. In particular, the conversion of the 2D image into a 3D image may be achieved by a deep learning algorithm, or the planar image may be 3D modeled by software such as CAD. Preferably, the image conversion unit searches for a corresponding three-dimensional honeycomb template in the template library based on the preview honeycomb pattern, and if so, the triggering feasibility judgment unit judges that the preview honeycomb pattern has feasibility, and finds a corresponding frame component pattern in the template library according to the three-dimensional honeycomb template/the preview honeycomb pattern; if not, the three-dimensional honeycomb model is generated based on the preview honeycomb pattern, and the trigger feasibility judging unit performs feasibility judgment based on the three-dimensional honeycomb model.

Bees need to nest on a comb foundation, which is arranged on a plate-like or sheet-like frame in the prior art. In order to make bees build a three-dimensional honeycomb, the shape of the frame needs to be correspondingly shaped according to the honeycomb shape customized by users. Therefore, after the 3D image of the honeycomb is obtained, a frame assembly is also required to be constructed according to the 3D image of the honeycomb, the process is that the category and the outline information of each object contained in the 3D honeycomb image are identified through a deep learning algorithm, and the shape characteristic information of each object in the 3D image is extracted through a visual algorithm; and constructing a frame assembly pattern according to the information. The frame assembly of the present invention comprises an integrated post and frame for a radial honeycomb; for a three-dimensional honeycomb comprising an outer mould and a frame, it is of course also possible to have an inner mould.

And the instruction compiling unit is used for compiling the frame assembly pattern into a 3D printing command or a CNC cutting parameter instruction so as to form the frame assembly pattern.

And the scheme design unit is used for planning the configuration scheme of the honeycomb according to the user order list. For a customer who orders a lot, according to the ordered quantity Q and the preset honeycomb structure type (see the storage unit in the management platform for details) and the historical ordering information of the customer, automatically matching corresponding product configuration schemes, for example, three-dimensional vase-shaped honeycomb structures N1, radial honeycomb structures N2, and a×n1+b×n2=q; of course, there are other matching schemes; these matching schemes are then fed back to the customer for determination.

In the invention, the processing equipment can be a 3D printer or CNC cutting. For different processing apparatuses, the instruction compiling unit may generate corresponding instructions.

The processing management unit is used for selecting processing equipment and issuing a frame assembly pattern; and receiving processing completion information uploaded by the processing equipment, wherein the processing completion information comprises processing equipment identity information, processing equipment position information, frame assembly serial numbers, user ID information and logistics information. Since there is more than one processing equipment and there is a possibility of distribution throughout the area, overall management is required. The processing management unit selects an idle processing device and sends processing confirmation information to the idle processing device; after the confirmation reply of the idle equipment is obtained, the frame assembly pattern is sent to the processing equipment; processing equipment processes according to the frame assembly pattern, and after processing, the processing equipment identity information, the processing equipment position information, the frame assembly serial number, the user ID information and the logistics information are uploaded. The frame assembly serial number needs to be bound to the user ID information, both unique and tracking friendly. And if the confirmation reply of the idle processing equipment is not obtained, searching for the next idle processing equipment until the confirmation reply is obtained.

The honey amount prediction unit is used for calculating the number of the comb foundations laid on the frame according to the frame assembly pattern/the three-dimensional honeycomb model/the three-dimensional honeycomb template; and predicting the honey production amount of the corresponding honeycomb according to the honeycomb foundation honey production historical data and the honeycomb foundation quantity. After the appearance shape of the honeycomb is designed, the user can also predict the honey yield according to the appearance shape of the honeycomb. After the honeycomb model or frame assembly image is constructed, the number of foundations that can be laid can be calculated based on the shape and size of the frame. Thus, the integral honey production data of the honeycomb is calculated according to the historical honey production data of the unit comb foundation. The yield estimation confirms to the user, and prompts the user to modify the parameters when the user finds that the preset quantity is exceeded. Conversely, the frame type and size can be tailored to the honey production of each cell for selection by the user. For example, the user inputs a honey amount to be ordered, the honey amount prediction unit may recommend various honeycomb types and sizes conforming to the range of honey amounts to be ordered according to the honey amount to be produced, and the user may select and adjust according to his own preference. For another example, for long-term collaboration clients, the scheme may also be automatically planned based on its historical data.

And the nesting information interaction module is used for interacting nesting related information.

Firstly, a bee grower obtains the logistic information of the frame assembly from the management platform through the nesting information interaction module and then obtains the frame assembly and corresponding user ID information. Then the frame components are assembled according to the requirements and then put into a beehive for nesting. And binding and uploading the beehive number with the user ID information and the frame assembly serial number. The information of bees and farmers in charge of raising bees can also be uploaded together.

In the process of honeybee nesting, the beehive environment information, the honeybee moving picture and the honeycomb building progress of the beehive can be uploaded, and the management platform issues the information according to the user ID information for corresponding users to review. In addition, the method can also carry out adaptability analysis according to the environmental information of the beehives, and feed back the result to the beekeeper through the nesting information interaction module, so that the beekeeper can conveniently adjust the result in time. The temperature and humidity control subsystem is arranged in the beehive and is used for feeding back the environmental information of the beehive and adjusting the environment (including temperature and humidity); the temperature and humidity control subsystem comprises a controller, a temperature sensor, a humidity sensor, a non-light heater and a ventilation fan.

The customized honeycomb obtained using the platform of the present invention will be described with reference to specific examples.

Referring to fig. 3 b-4, a three-dimensional honeycomb template of a vase-like three-dimensional honeycomb structure comprises a three-dimensional frame body 2 (the corresponding front or side view of which can be seen as a corresponding two-dimensional honeycomb pattern, as shown in fig. 3 a) for supporting a honeycomb, the outer surface of the three-dimensional frame body 2 being provided with a number of mounting seats (which can correspond to each of the trapezoidal foundation units in fig. 3 a) for arranging a comb foundation; an outer mold 1 is sleeved outside the three-dimensional frame body 2, and a gap is reserved between a mold cavity of the outer mold 1 and the three-dimensional frame body 2; at least two inlets and outlets are formed in the outer die 1, and the two inlets and outlets are respectively arranged at the top and the bottom of the outer die 1; the three-dimensional frame 2 is fixed on the bottom plate 3, and a hollow-out 31 communicated with the inlet and the outlet of the outer die is arranged on the bottom plate 3.

The principle is as follows: through setting up external mold 1 to set up the clearance that supplies the honeybee motion to nest (also reserve the space of buildding the septum and remove for the honeybee) between external mold 1 and three-dimensional frame body 2, this clearance provides a space sense for the honeybee, and sets up the access respectively in top and bottom, accords with the honeybee and builds the physiological demand to the space when nesting, and from top to bottom, perhaps from bottom to top's law of motion, thereby guarantees that the honeybee not only can get into wherein normally carrying out the work of nesting smoothly, and, its time of annotating the honeybee of nesting also does not lengthen greatly.

In order to facilitate bees to nest inside the three-dimensional frame body 2 to increase honey yield, the three-dimensional frame body 2 is hollow, and an opening for accessing the hollow part is formed in the three-dimensional frame body 2. Of course, it is contemplated that the inner surface of the three-dimensional frame body 2 could also be provided with a plurality of mounting seats for placement of the comb foundation (of course, the three-dimensional frame body could also be configured directly as hollowed-out, see fig. 5). The openings in the three-dimensional frame body 2 can be provided on top of it. Of course, in other embodiments, the space frame body 2 may not be hollow, or the hollow portion may not be provided with an opening, as shown in fig. 6 and 7. In this embodiment, the mounting base is a recess conforming to the shape of the comb foundation, and the depth thereof is preferably 1 to 3 mm.

The shape of the die cavity of the outer die 1 can be consistent with the shape of the outer outline of the three-dimensional frame body 2, and the width of a gap between the die cavity of the outer die 1 and the three-dimensional frame body 2 is 2-3 cm. Too small clearance is unfavorable for the honeybee flight to annotate the external mold and three-dimensional frame body adhesion easily when carrying out the honey after nesting, influence the later stage drawing of patterns. Too large gaps can not provide necessary space sense for bees, and the efficiency of honeybee nesting is affected.

In addition, for facilitating demolding, referring to fig. 4-7, the outer mold 1 is formed by splicing left and right parts, the left and right outer molds 1 are provided with bases 12, and the shapes and the sizes of the bases 12 of the left and right outer molds 1 are consistent with those of the bottom plate 3. The base 12 has the effect of enabling the outer mould 1 to be placed more firmly, and the base 12 and the bottom plate 3 are arranged to be consistent in shape and size, so that the three-dimensional frame body 2 is more convenient to center in the mould cavity. Of course, for centering purposes, a positioning connector for positioning connection is arranged between the bottom plate 3 and the three-dimensional frame body 2. In the embodiment, a positioning lug 32 is arranged on the center of the bottom plate 3, and a positioning groove matched with the positioning lug 32 is arranged at the bottom of the three-dimensional frame body 2. Thus, the connection of the two is convenient, the positioning of the two is also convenient, and the centering of the positioning frame body 2 is also convenient. The left and right outer mold 1 can be provided with positioning connectors which are convenient for positioning connection. In this embodiment, the connecting piece is disposed on the flange 11 along the edges of the left and right outer dies, and the flange 11 may be provided with a positioning boss 13 and a positioning groove 14 that are mutually matched.

Of course, in other embodiments, the outer membrane is divided into more than two parts, or the outer membrane may not be provided in two parts, but rather is a separate whole, as will be appreciated, as long as it is adapted to the shape of the three-dimensional frame body 2, and that the gap between the outer membrane and the three-dimensional frame body 2 is the corresponding condition. For example, referring to fig. 10, only one outer membrane 1 of a corresponding shape need be provided outside the three-dimensional frame body 2. Of course, further, if the space inside the three-dimensional frame body 2 is large (for example, the inner diameter of the annular three-dimensional frame body is large), the inner mold 15 may be provided inside the three-dimensional frame body 2 to guide bees to nest inside the frame body, and the gap between the outer wall of the inner mold 15 and the inner side of the three-dimensional frame body 2 may be 2-3cm.

In this embodiment, referring to fig. 3b, the included angle between the base unit and the base unit, and between the base unit and the bottom plate of the three-dimensional frame body 2 is greater than 30 °. The purpose is to avoid the generation of dead angles where bees cannot enter the nest, so that the three-dimensional honeycomb shape finally obtained is incomplete. In order to enable the honeycomb to stand stably, the bottom area S2 of the three-dimensional frame body 2 should be at least 75% or more of the top area S1.

In order to facilitate the bees to enter, the number and the positions of the hollowed-out parts 31 on the bottom plate 3 correspond to those of the vertical faces of the three-dimensional frame body 2. For example, in this embodiment, the three-dimensional frame body 2 is divided into 8 groups of vertical faces, and then eight hollowed-out parts 31 are correspondingly arranged on the bottom plate 3. Of course, the above-mentioned three-dimensional frame body 2 can also have other shapes such as spherical, annular, etc., see fig. 6 and 7.

Referring to fig. 8-9, a splittable radial honeycomb structure, comprising: integration stake 21 and frame; the outer wall of the integrated pile 21 is provided with a plurality of groove slideways; the frame comprises a male frame 22 and a frame 23 (the frame is formed by splicing three rectangular base contours and three fan-shaped base contours along an axis, each filled by a base unit of corresponding shape); the male frame 22 is connected to the frame 23; the convex frame 22 of the frame is disposed within the recessed ramp; the inner wall of the frame 23 is provided with grooves; the grooves are used for placing the comb foundation.

The design is different from parallel arrangement frames, the combination is in a radial form from the center, a plurality of groove slide ways are arranged on one circle of the integrated pile, a corresponding number of frames can be inserted into the integrated pile, different modeling frames can be manufactured according to the required honeycomb honey modeling, and the integrity and the ornamental value of the honeycomb are ensured. The frame comprises a male frame 22 and a frame 23, the male frame 22 and the frame 23 are internally provided with grooves, the comb foundation is inserted into the grooves of the frame 23 when in use, and then the male frame 22 and the frame 23 are buckled and inserted into the spud 21.

Further, the top end of the integrated pile is convex, and the lower half part of the integrated pile is concave; in the embodiment, the integrated pile is cylindrical, and a plurality of cylindrical columns can be stacked, so that display is facilitated. Typically, the stake will be of the default design described above, although the stake may be custom-formed in other shapes. Further, the male frame and the frame are snap-fit. Further, the number of the frames corresponds to the number of the groove slideways arranged on the integrated piles one by one.

When the corresponding honeycomb processing is finished, the honeycomb foundation is firstly placed in the groove of the honeycomb frame, then the convex frame is buckled with the honeycomb frame provided with the honeycomb foundation, and the honeycomb foundation is placed in the groove of the integrated pile to finish the operation. Because the top of integrated stake is protruding, and the latter half is the indent, in the practical application in-process, the height of integrated stake can be adjusted according to the demand, can a plurality of integrated stake upper and lower combinations simultaneously. When the integrated pile is particularly used, the size of the integrated pile can be selected according to the requirements, and the shape of the frame can be designed; in other embodiments, the stakes can take on other sizes and the frames can take on other shapes.

The frame capable of being spliced and radial can be used for constructing the heights of the personalized modeling frame and the integrated piles according to the requirements to obtain the honeycomb honey block with the modeling; the structure is simple, the installation is convenient, and the practicability is strong; the required frame can be selected to be directly extracted according to the requirement when the comb honey is taken, so that the integrity of the comb can be ensured, the ornamental value and commodity value of the product can be improved, and the comb honey is suitable to be used as a gift comb honey product; each frame can be clamped into the groove slideway, so that the function of fixing the comb honey box can be achieved; the honeycomb frame with the modeling is convenient for users to take and share honeycomb honey according to the needs.

Referring to fig. 9, another annular array radial honeycomb structure comprises: a body and a honeycomb panel; in this embodiment, a cylindrical body and a twisted honeycomb panel 24 (i.e., a base profile) are employed; the whole body is not only a complete single body, but also can realize that a plurality of groups of stacks are in a new form. The upper end and the lower end of the cylindrical main body are open, the cross section of the inner cavity is rectangular, and a plurality of groups of groove slideways are formed in the circumference of the outer wall of the cylindrical main body. Inserting a torsional honeycomb plate 24 into the cylindrical main body groove slideway, wherein the torsional honeycomb plate 24 corresponds to and is inserted into the cylindrical main body groove slideway one by one; the thin inserting sheet is used for being placed into a honey producing environment after the comb foundation is pasted. In this embodiment, ten twisted honeycomb plates 24 are clamped into the corresponding groove slides. In other embodiments, the number of the twisted honeycomb plates can be adjusted according to the requirement, and the twisted honeycomb plates are in one-to-one correspondence with the groove slideways arranged on the cylindrical main body.

And a connecting piece corresponding to the main body groove slideway is arranged on one side of the straight edge of the torsional honeycomb plate, and the connecting piece links the cylindrical main body and the torsional honeycomb plate. The two sides of the connecting piece and the torsional honeycomb board are respectively provided with a gap of 10mm, the bee nest is used for the bee farmers to splice the comb foundations to form the bee paths.

When the honeycomb corresponding to the radial honeycomb structure is processed and put into use, the annular array type radial honeycomb can be placed in a common beehive, and bees can build the honeycomb on the torsional inserting sheet which is provided with the honeycomb foundation and the honey and brew the honey. When it is desired to remove the honeycomb honey, the cylindrical body is removed together with the twisted honeycomb plate 24, and then the twisted honeycomb plate 24 is removed alone with the honeycomb honey thereon. The integrity of the honeycomb is not damaged, the ornamental value is high, and the honeycomb honey product is suitable to be used as a gift honeycomb honey product. Realize that a pot of honey is shared to inserted sheet formula structure many people.

As shown in fig. 2, the present invention further provides a personalized honeycomb customized service method, which includes:

s1, acquiring the customized honeycomb image information of the user, and binding the honeycomb image information with the user ID of the user.

In some embodiments, the user may select the two-dimensional mode or the three-dimensional mode in advance according to actual needs, so that a corresponding two-dimensional preview honeycomb pattern or a corresponding three-dimensional preview honeycomb pattern may be automatically generated after the honeycomb parameters are currently set. If the two-dimensional preview honeycomb pattern is adopted, the two-dimensional preview honeycomb pattern is correspondingly converted into a three-dimensional honeycomb model before the feasibility judgment is carried out. Preferably, the two-dimensional mode is automatically defaulted, so that the difficulty of user design is reduced.

In some embodiments, the cell image information includes a cell type and a preview cell pattern generated based on each cell template specified by the user in the template library. Wherein the honeycomb type comprises: a three-dimensional honeycomb structure and a radial honeycomb structure.

In some embodiments, after a user enters the system or platform, the type of honeycomb to be customized is specified, and then the corresponding honeycomb template is selected from a corresponding template library of the platform according to the prompt.

In some embodiments, the honeycomb templates of the three-dimensional honeycomb structure in the template library include two types, one type as a base profile and one type as a base unit.

In some embodiments, the template library, the honeycomb templates of the radial honeycomb structure comprise: the basic profile of each frame, e.g., twisted (see fig. 9), freeform, regular or irregular planar formed by the stitching of the base units.

In some embodiments, after the user designates the corresponding honeycomb template in the template library, the user may zoom in or zoom out the designated honeycomb template in the user interface, or change the size of the honeycomb template by attribute editing, etc., and then splice the honeycomb templates together by moving or dragging or rotating, etc., to obtain the corresponding preview honeycomb pattern. For example, after the basic outlines are selected, the basic outlines are spliced to form an outer outline of the elliptical three-dimensional frame body, and then corresponding filling basic units are selected for each basic outline, so that a two-dimensional preview honeycomb pattern corresponding to the three-dimensional frame body can be obtained. Because the outer membrane/inner mould has a corresponding relation with the three-dimensional frame body, when the three-dimensional frame body is converted into a three-dimensional pattern, the corresponding outer membrane or inner mould can be automatically generated based on the two-dimensional preview honeycomb pattern corresponding to the three-dimensional frame body. The user may also designate the base profile and base unit of the outer or inner mold, respectively, in the manner described above. Accordingly, the user can only relate to the outer outline of the three-dimensional frame body, and other components can be automatically matched or adaptively generated. Of course, the user can also replace or delete the honeycomb templates according to actual needs.

In other embodiments, the platform provides at least two modes of customization. For example, a scientific practice mode, which is mainly used for practice learning by pupils and the like. As another example, business models are primarily used for customized honeycomb designs for users who need to purchase honey. Further, the platform can also calculate the quantity of the comb foundations paved on the frame according to the previewed honeycomb pattern, and then calculate the honey production quantity of the honeycomb corresponding to the frame component according to the honey production historical data of the comb foundations and the quantity of the comb foundations; the frame type and size is then automatically programmed for selection by the user directly based on the honey production of the corresponding honeycomb structure, the ordered honey input by the user, and historical data (e.g., the three-dimensional honeycomb structure morphology of the historical order).

S2, converting the preview honeycomb pattern in the honeycomb image information into a corresponding three-dimensional honeycomb model, judging the feasibility of the preview honeycomb pattern in the honeycomb image information based on the three-dimensional honeycomb model, if the feasibility exists, executing the step S3, otherwise, executing the step S4. In some embodiments, the corresponding three-dimensional honeycomb template may be matched in the template library in advance based on the preview honeycomb pattern, if so, the preview honeycomb pattern is determined to have feasibility (of course, if the template is modified by the user, the feasibility is also determined), if not, the corresponding three-dimensional honeycomb template is converted into a three-dimensional honeycomb model, and the reliability determination is performed based on the three-dimensional honeycomb model. In some embodiments, for a three-dimensional honeycomb structure, the feasibility criteria are: after the three-dimensional honeycomb model is centered, the minimum distance between each basic unit on the outer membrane and each side of the inner wall of the pre-constructed simulated beehive is larger than a preset size threshold (such as 100 mm), so that a manufacturing space is reserved for manufacturing the honeycomb in the beehive; in addition, the included angle between the basic units extending along the axial direction on the three-dimensional frame body is larger than a preset angle threshold (for example, 30 degrees; if the included angle is smaller than the preset angle threshold, the two adjacent basic units extending along the axial direction are easy to adhere together when the three-dimensional honeycomb structure is actually produced or when the three-dimensional honeycomb structure is sealed for nesting and injecting honey; and, the clearance between the basic unit on the three-dimensional frame body and the corresponding basic unit on the adventitia satisfies: 2-3cm;

For the upright honeycomb structure with the internal mold, the following requirements are also satisfied: each basic unit on the inner mold also needs to meet the above angle conditions, and meanwhile, the gap between the basic unit on the three-dimensional frame body and the corresponding basic unit on the inner film meets the following conditions: 2-3cm;

for a three-dimensional frame body with a bottom surface (i.e., a base unit is provided at the bottom of the three-dimensional frame body, or a plane formed by splicing a plurality of base units and capable of being butted with a bottom plate), it is also necessary to satisfy the following requirements: the angle between the bottom surface and the surrounding base unit is also larger than a preset angle threshold (e.g., 30 °);

for a three-dimensional frame body having a bottom surface and a top surface (i.e., the bottom and top of the three-dimensional frame body have a base unit, respectively, or a plane formed by splicing a plurality of base units that can be butted with a bottom plate), it is also necessary to satisfy: the ratio of the surface area of the bottom surface to the surface area of the top surface is greater than a predetermined ratio threshold (e.g., 3/4).

In some embodiments, the criteria for feasibility for a radial honeycomb structure are: after the honeycomb is centered, the minimum distance between the edge of each frame and each side of the inner wall of the pre-constructed simulated beehive is larger than a preset size threshold (such as 100 mm), so that a manufacturing space is reserved for manufacturing the honeycomb in the beehive; and the minimum spacing between adjacent two frame frames is greater than a preset spacing threshold (e.g., 3 cm).

S3, generating a frame assembly pattern based on the three-dimensional honeycomb model corresponding to the preview honeycomb pattern with feasibility, and sending the frame assembly pattern to processing equipment to trigger the frame assembly processing equipment to process the corresponding frame assembly. In some embodiments, if a corresponding three-dimensional honeycomb template is previously matched in the template library based on the preview honeycomb pattern, a corresponding frame element pattern may be correspondingly matched in the database according to the preview honeycomb pattern. In some embodiments, the frame assembly pattern is compiled, converted to 3D print commands or CNC cutting parameters, and sent to the corresponding processing equipment for processing. Specifically, firstly, processing confirmation information is sent to idle processing equipment; after confirmation reply is obtained, the pattern is sent to the processing equipment; processing equipment processes according to the pattern, and after the processing is finished, uploading processing equipment identity information, processing equipment position information, frame assembly serial numbers, user ID information and logistics information; if the confirmation reply is not obtained, searching for the next idle processing equipment until the confirmation reply is obtained.

S4, automatically adjusting the preview honeycomb pattern according to a preset feasibility judging standard to obtain a new feasibility preview honeycomb pattern, and executing step S3. Of course, if the automatically adjusted preview honeycomb pattern is not viable, the preview honeycomb pattern is fed back to the user for parameter modification or re-customization.

S5, after the beekeeper puts the frame component into the beehive for nesting, and relevant nesting information monitored in real time through the monitoring equipment is uploaded. In some embodiments, after the processing device finishes processing, the beekeeper is notified, specifically, a corresponding message may be sent to a user terminal of the beekeeper through the internet of things, or a corresponding prompt message may be directly displayed on a user interface of the corresponding device. In some embodiments, the monitoring may be performed in real time by pre-installing monitoring equipment within the beehive.

S6, corresponding nesting related information is issued according to the user ID.

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 apparatus 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 apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element. The embodiments of the present invention have been described above with reference to the accompanying drawings, but the present invention is not limited to the above-described embodiments, which are merely illustrative and not restrictive, and many forms may be made by those having ordinary skill in the art without departing from the spirit of the present invention and the scope of the claims, which are to be protected by the present invention.

Claims (10)

1. A personalized cellular customization service system, comprising:

a template library for providing a user with a honeycomb template; the honeycomb template comprises a base profile for forming an outer profile of a honeycomb frame, and a base unit for filling the base profile;

the user interaction module is used for acquiring the honeycomb image information customized by the user and binding the honeycomb image information with the user ID of the user; the honeycomb image information includes: a cell type, and a two-dimensional preview cell pattern generated based on the cell template specified by the user;

the management platform is used for receiving the honeycomb image information sent by the user interaction module, judging the feasibility of the preview honeycomb pattern, converting the preview honeycomb pattern into a corresponding frame assembly pattern when judging that the preview honeycomb pattern has the feasibility, and then sending the frame assembly pattern to processing equipment so as to trigger the processing equipment to process the corresponding frame assembly; then receiving the frame component processing completion information uploaded by the processing equipment, informing a beekeeper to splice the frame component and then placing the spliced frame component into a beehive for nesting; receiving nesting related information and issuing the nesting related information according to the corresponding user ID;

The nesting information interaction module is used for interacting nesting related information;

wherein, the management platform includes: the image conversion unit is used for searching a corresponding three-dimensional honeycomb template in the template library based on the preview honeycomb pattern, and if the corresponding three-dimensional honeycomb template is found, the triggering feasibility judgment unit judges that the preview honeycomb pattern has feasibility, and the corresponding frame assembly pattern is found in the template library according to the three-dimensional honeycomb template; if not, converting the preview honeycomb pattern into a three-dimensional honeycomb model, so as to judge the feasibility of the preview honeycomb pattern based on the three-dimensional honeycomb model; and when the preview honeycomb pattern is judged to be feasible, generating a corresponding frame assembly pattern based on the three-dimensional honeycomb model corresponding to the preview honeycomb pattern;

the feasibility judging unit is used for judging whether the minimum distance between each basic unit on the outer mold in the three-dimensional honeycomb structure and the corresponding inner wall in the simulation beehive is larger than a preset size threshold value or not after the three-dimensional honeycomb model/the three-dimensional honeycomb template is placed in the preset simulation beehive in the middle when the honeycomb type is identified as the three-dimensional honeycomb structure, and whether the included angle between the basic units extending along the axis direction on the three-dimensional honeycomb frame body in the three-dimensional honeycomb structure and the included angle between the basic units extending along the axis direction on the outer mold in the three-dimensional honeycomb structure are larger than a preset angle threshold value or not; and gaps between the basic units on the three-dimensional frame body and the corresponding basic units on the outer mold meet a preset gap threshold range; if yes, judging that the preview honeycomb pattern has feasibility; or, when the honeycomb type is identified as a radial honeycomb structure, judging whether the minimum distance between the edge of each basic outline in the radial honeycomb structure and the corresponding inner wall in the simulation beehive is greater than a preset size threshold value or not after the three-dimensional honeycomb model/the three-dimensional honeycomb template is placed in the preset simulation beehive in the middle, and whether the distance between two adjacent basic outlines in the radial honeycomb structure is greater than a preset distance threshold value or not, if so, judging that the preview honeycomb pattern has feasibility, and triggering the image conversion unit to generate the corresponding frame assembly pattern.

2. The personalized honeycomb customization service system according to claim 1, wherein the feasibility judging unit is further configured to judge whether an included angle between base units extending in an axial direction of each base unit on an internal mold is larger than an angle threshold value when the stereoscopic honeycomb structure is recognized as having the internal mold; and gaps between the basic units on the three-dimensional frame body and the corresponding basic units on the inner mold meet a preset gap threshold range; if yes, judging that the preview honeycomb pattern has feasibility; and/or the number of the groups of groups,

when the three-dimensional honeycomb structure is identified to be provided with a bottom surface and a top surface, judging whether an included angle between the bottom surface and surrounding basic units is larger than a preset angle threshold value, judging whether the ratio of the surface area of the bottom surface to the surface area of the top surface is larger than a preset ratio threshold value, and if so, judging that the preview honeycomb pattern is feasible.

3. A personalized cellular customization service system according to claim 1, wherein the user interaction module comprises:

the visual design unit is used for generating the two-dimensional preview honeycomb pattern according to the honeycomb parameters input by the user; the honeycomb parameters comprise honeycomb types, honeycomb templates designated by users in the template library and a combination mode of the honeycomb templates; and/or the number of the groups of groups,

The feasibility judging unit is further configured to automatically adjust the preview honeycomb pattern based on a preset feasibility judging standard when the feasibility judging unit judges that the preview honeycomb pattern is not feasible, and regenerate the preview honeycomb pattern with feasibility.

4. A personalized cellular customization service system according to claim 3, wherein the management platform further comprises:

the storage unit is used for storing the user ID information and the honeycomb image information uploaded by the user interaction module; storing the nesting related information uploaded by the nesting information interaction module; and/or the number of the groups of groups,

the command compiling unit is used for compiling the frame assembly patterns into 3D printing commands or CNC cutting parameter commands; and/or the number of the groups of groups,

a honey amount prediction unit for calculating a comb foundation amount according to the three-dimensional honeycomb model/the three-dimensional honeycomb template/the frame assembly pattern; predicting the honey production amount of the corresponding honeycomb according to the honeycomb foundation honey production historical data and the honeycomb foundation quantity; and/or the number of the groups of groups,

and the scheme design unit is used for planning the required honeycomb types and the required honeycomb amounts according to the order list of the user and historical order data, wherein the order list comprises the ordered honey amounts, and the historical order data comprises the honeycomb types, the honeycomb sizes and the honeycomb amounts used in the history.

5. A personalized cellular customization service system according to claim 3, wherein the management platform further comprises:

the processing management unit is used for selecting processing equipment and issuing the frame assembly patterns; receiving processing completion information uploaded by the processing equipment, wherein the processing completion information comprises processing equipment identity information, processing equipment position information, frame assembly serial numbers, user ID information and logistics information; and/or the number of the groups of groups,

the honeycomb customized service system also comprises a temperature and humidity control subsystem arranged in the beehive; the temperature and humidity control subsystem comprises a controller, a temperature sensor, a humidity sensor, a non-light heater and a ventilation fan.

6. A method of personalizing a cellular subscription service, comprising:

acquiring customized honeycomb image information of a user, and binding the honeycomb image information with a user ID of the user; the honeycomb image information includes a honeycomb type, and a two-dimensional preview honeycomb pattern generated based on each honeycomb template specified by the user in a template library; the honeycomb template comprises a basic contour for forming an outer contour of a honeycomb and a basic unit for filling the basic contour;

Searching a corresponding three-dimensional honeycomb template in a template library based on the preview honeycomb pattern, if so, judging that the preview honeycomb pattern has feasibility, and searching a corresponding frame assembly pattern in the template library according to the three-dimensional honeycomb template; if not, generating a three-dimensional honeycomb model based on the preview honeycomb pattern, and judging the feasibility of the preview honeycomb pattern by combining with a preset feasibility judging standard; when the preview honeycomb pattern is judged to have feasibility, generating a corresponding frame assembly pattern based on a three-dimensional honeycomb model for the preview honeycomb pattern with feasibility, and sending the frame assembly pattern to processing equipment so as to trigger the processing equipment to process a corresponding frame assembly, and informing a beekeeper to put the frame assembly into a beehive for nesting;

after the frame component is placed into a beehive for nesting, the nesting related information is uploaded; and corresponding nesting related information is issued according to the user ID;

wherein the step of judging the feasibility of the preview honeycomb pattern includes:

identifying a honeycomb type;

if the honeycomb type is a three-dimensional honeycomb structure, judging whether the distance between each basic unit on the outer mold in the three-dimensional honeycomb structure and the corresponding inner wall in the simulated beehive is larger than a preset size threshold value or not when the three-dimensional honeycomb model/the three-dimensional honeycomb template is placed in the preset simulated beehive in the middle, and whether the included angles between the basic units extending along the axial direction on the three-dimensional honeycomb frame body in the three-dimensional honeycomb structure and the included angles between the basic units extending along the axial direction on the outer mold in the three-dimensional honeycomb structure are larger than an angle threshold value or not; and gaps between the basic units on the three-dimensional frame body and the corresponding basic units on the outer mold meet a preset gap threshold range; if yes, judging that the preview honeycomb pattern has feasibility; or if the honeycomb type is a radial honeycomb structure, judging whether the minimum distance between the edge of each basic outline in the radial honeycomb structure and the corresponding inner wall in the simulation beehive is larger than a preset size threshold value or not after the three-dimensional honeycomb model/the three-dimensional honeycomb template is placed in the preset simulation beehive in the middle, and judging whether the distance between two adjacent sheets of the radial honeycomb structure is larger than a preset distance threshold value or not if so, wherein the preview honeycomb pattern has feasibility.

7. The personalized honeycomb customization service method according to claim 6, wherein the step of determining the feasibility of the preview honeycomb pattern further comprises:

if the three-dimensional honeycomb structure is provided with an inner die, judging whether an included angle between foundation units extending along the axis direction of each foundation unit on the inner die is larger than an angle threshold value or not; and gaps between the basic units on the three-dimensional frame body and the corresponding basic units on the inner mold meet a preset gap threshold range; if yes, judging that the preview honeycomb pattern has feasibility.

8. The personalized honeycomb customization service method according to claim 7, wherein the step of determining the feasibility of the preview honeycomb pattern further comprises:

if the three-dimensional honeycomb structure is provided with a bottom surface, judging whether an included angle between the bottom surface and the surrounding basic units is larger than a preset angle threshold value or not; if yes, judging that the preview honeycomb pattern has feasibility; or alternatively

If the three-dimensional honeycomb structure is provided with a bottom surface and a top surface, judging whether an included angle between the bottom surface and surrounding basic units is larger than a preset angle threshold value, and whether the ratio of the surface area of the bottom surface to the surface area of the top surface is larger than a preset ratio threshold value, if so, judging that the preview honeycomb pattern is feasible.

9. The personalized honeycomb customization service method of claim 6, wherein the step of processing the frame assembly comprises:

transmitting processing confirmation information to the idle processing equipment; after confirmation and reply are obtained, the frame assembly pattern is sent to the processing equipment;

the processing equipment processes according to the frame assembly pattern, and uploads processing equipment identity information, processing equipment position information, frame assembly serial numbers, user ID information and logistics information after processing is finished;

if the confirmation reply is not obtained, searching for the next idle processing equipment until the confirmation reply is obtained.

10. A personalized honeycomb customized service method according to claim 7, further comprising the steps of:

calculating the number of comb foundations according to the three-dimensional honeycomb model/the three-dimensional honeycomb template/the frame assembly pattern; predicting the honey production amount of the corresponding honeycomb according to the honeycomb foundation honey production historical data and the honeycomb foundation quantity; or alternatively, the process may be performed,

planning the required honeycomb types and the required honeycomb amounts according to the order list of the user and historical order data, wherein the order list comprises honey amounts, and the historical order data comprises the honeycomb types, the honeycomb sizes and the honeycomb amounts used in the history.