CN113393570A - Method and system for constructing three-dimensional model of reactor - Google Patents

Abstract

A method and a system for constructing a three-dimensional model of a reactor are provided. The construction method of the three-dimensional model of the reactor comprises the following steps: controlling three-dimensional modeling software to output a three-dimensional model of a preset reactor, wherein the three-dimensional model of the preset reactor is assembled by sub three-dimensional models of at least one component of the preset reactor; obtaining a modification operation on at least one physical structure parameter of at least one sub three-dimensional model; adjusting the physical structure of the corresponding sub-three-dimensional model according to the modification operation; and assembling the sub three-dimensional model with the adjusted physical structure and other sub three-dimensional models of the preset reactor to construct a three-dimensional model of the reactor. The method and the system for constructing the three-dimensional model of the nuclear reactor can enable designers of the nuclear reactor to quickly complete the scheme design of the nuclear reactor, and improve the design efficiency of the reactor.

Description

Method and system for constructing three-dimensional model of reactor

Technical Field

The application relates to the technical field of reactors, in particular to a method and a system for constructing a three-dimensional model of a reactor.

Background

The reactor is also called a nuclear reactor or a nuclear reactor, and is a device capable of maintaining a controllable self-sustaining chain type nuclear fission reaction so as to realize nuclear energy utilization. The structure of the reactor is complex, so that the design process of the reactor is also complex, and the design efficiency of the reactor in the related art is not high.

Disclosure of Invention

One aspect of the present application provides a method for constructing a three-dimensional model of a reactor, including: controlling three-dimensional modeling software to output a three-dimensional model of a preset reactor, wherein the three-dimensional model of the preset reactor is assembled by sub three-dimensional models of at least one component of the preset reactor; obtaining a modification operation on at least one physical structure parameter of at least one sub three-dimensional model; adjusting the physical structure of the corresponding sub three-dimensional model according to the modification operation; assembling the sub three-dimensional model after adjusting the physical structure and other sub three-dimensional models of the preset reactor to construct a three-dimensional model of the reactor.

Another aspect of the present application provides a system for constructing a three-dimensional model of a reactor, including: the controller comprises a memory and a processor, wherein a control program is stored in the memory, and when the control program is executed by the processor, the control program is used for realizing any one of the construction methods.

Drawings

Other objects and advantages of the present application will become apparent from the following description of the present application with reference to the accompanying drawings, and may help to provide a thorough understanding of the present application.

FIG. 1 is a schematic diagram of a reactor configuration according to one embodiment of the present application;

FIG. 2 is a flow diagram of a construction method according to one embodiment of the present application;

FIG. 3 is a flow chart of selecting a pump support model according to one embodiment of the present application;

FIG. 4 is a diagram of a dialog box in a build method according to one embodiment of the present application;

FIG. 5 is a schematic illustration of a three-dimensional model of a stack container, a shield assembly, and a pump support assembly prior to adjustment according to one embodiment of the present application;

FIG. 6 is a schematic view of a three-dimensional model of a stack container, a shield assembly, and a pump support assembly after adjustment, according to one embodiment of the present application.

It is noted that the drawings are not necessarily to scale and are merely illustrative in nature and not intended to obscure the reader.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more clear, the technical solutions of the present application will be described below in detail and completely with reference to the accompanying drawings of the embodiments of the present application. It should be apparent that the described embodiment is one embodiment of the present application and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the described embodiments of the application without any inventive step, are within the scope of protection of the application.

Unless defined otherwise, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this application belongs.

The embodiment of the application firstly provides a method for constructing a three-dimensional model of a reactor. The reactor is also called as a nuclear reactor or a nuclear reactor, and is a device capable of maintaining a controllable self-sustaining chain type nuclear fission reaction to realize the utilization of nuclear energy, the structure of the reactor is more complex, in particular to a pool type fast reactor, a main heat transmission device, an accident residual heat discharge device, a reactor system device and an in-reactor refueling device on the reactor are all arranged in a reactor container, and the in-reactor components comprise a plurality of in-reactor device supporting structures and in-reactor shielding structures. The overall arrangement of the equipment, the reactor container and the reactor internals on the reactor is a key technology in the reactor design scheme, reflects the technical level of a design unit and the soft strength of the design unit, and when the design scheme of the reactor body is made, the arrangement scheme of the whole reactor body needs to be made, so that the screening, comparison and decision of the design scheme are facilitated.

Fig. 1 is a schematic structural diagram of a reactor according to an embodiment of the present application, and as shown in fig. 1, a sodium-cooled fast reactor 1 may include a reactor vessel 20, a core 30 disposed in the reactor vessel 20, an intermediate heat exchanger 40, a grid header 50, and a driving unit 60 for driving liquid sodium to flow, and a shielding assembly 10, taking a sodium-cooled fast reactor as an example. The shield assembly 10 may include: a radially outer shield 101 disposed radially outwardly of the core 30 and extending axially, a radially inner shield 102 disposed between the core 30 and the radially outer shield 101, a middle shield 103 disposed above the radially outer shield 101, an upper shield 104 disposed above the middle shield 103, and a lower shield 105 disposed radially outwardly of the cascade plate header 50 below the radially outer shield 101. The sodium-cooled fast reactor 1 also comprises an in-reactor support 70, and the in-reactor support 70 comprises an upper support plate 71 positioned at the upper part, a middle support plate 72 positioned at the middle part and a bottom support plate 73 positioned at the bottom part.

Not only sodium-cooled fast reactors, but also other types of reactors are also complicated in structure, and include, for example, a reactor pressure vessel irradiation monitoring tube, a reactor pressure vessel insulating layer, a control rod driving mechanism, a reactor top structure, an internal reactor component, a reactor support, a primary shielding structure, and the like.

Fig. 2 is a flowchart of a method for constructing a three-dimensional model of a reactor according to an embodiment of the present application, and as shown in fig. 2, the method for constructing a three-dimensional model of a reactor according to an embodiment of the present application includes steps S202, S204, S206, and S208, which are as follows:

step S202: and controlling the three-dimensional modeling software to output a three-dimensional model of the preset reactor, wherein the three-dimensional model of the preset reactor is assembled by sub three-dimensional models of at least one component of the preset reactor.

That is, a three-dimensional model of a predetermined reactor having three-dimensional data is constructed through a virtual three-dimensional space using three-dimensional modeling software. The three-dimensional modeling software can be CATIA software for example, and the CATIA software can be applied to the design fields of airplanes, automobiles, ships, nuclear reactors and the like by virtue of the powerful curved surface design function of the CATIA software; for example, the three-dimensional modeling software can be Pro-E software, Pro-E is short for Pro/Engineer, more commonly is short for ProE or Pro/E, and Pro-E adopts a modular mode, so that a user can select the software according to the self requirement without installing all modules; also for example, the three-dimensional modeling software may be UG software, solidworks software, or the like. Specifically, the designer can select appropriate three-dimensional modeling software according to the own requirements.

The components of the reactor may be, for example, the above-mentioned reactor vessel, support structure, reactor core, shielding assembly, etc., and accordingly, each sub-three-dimensional model represents three-dimensional data of the corresponding component constructed in the virtual three-dimensional space, for example, a first sub-three-dimensional model represents three-dimensional data of the reactor vessel constructed in the virtual three-dimensional space, a second sub-three-dimensional model represents three-dimensional data of the support structure constructed in the virtual three-dimensional space, a third sub-three-dimensional model represents three-dimensional data of the reactor core constructed in the virtual three-dimensional space, a fourth sub-three-dimensional model represents three-dimensional data of the shielding assembly constructed in the virtual three-dimensional space, etc.

Step S204: and acquiring a modification operation on at least one physical structure parameter of at least one sub three-dimensional model.

Taking the drive unit as a pump and taking the modification operation of obtaining the physical structure parameter of the support structure of the pump as an example, the modeling method may provide an interactive interface through which a user issues the corresponding modification operation, and a specific example is given below.

FIG. 3 is a flow chart illustrating the selection of a pump bearing model according to an embodiment of the present application, and as shown in FIG. 3, the model associated with the pump bearing may be opened by the flow chart shown in FIG. 3, i.e., selecting a formula operation (which will be described in more detail later on), selecting the pump bearing model, then selecting the "flow chart" tab, clicking the "interactive execution" command in the toolbar below the "flow chart", and then clicking a gesture icon button (not shown) on the right side of the "assembly node" box in the pop-up dialog box.

FIG. 4 is a schematic diagram of a dialog box in a construction method according to an embodiment of the present application, as shown in FIG. 4, with the character "Pump support" indicating the selected pump support model on the upper left side of the dialog box, a virtual button for answering a question of the operation of the dialog box on the upper right side of the dialog box, and a virtual button for closing the dialog box; the middle part of the dialog box can display the currently assembled node and the name of the part, wherein an operator can select a product node in the assembling environment of the three-dimensional modeling software and then input a corresponding name in a text box corresponding to the name of the part, and the middle part of the dialog box is also provided with a display interface for design input and design output, wherein the display interface for the design input can receive the input of the operator. The lower left side of the dialog box is a "knowledge base" virtual button that can provide knowledge related to the pump support, and the lower right side of the dialog box is an "ok" button and a "cancel" button for determining or canceling the associated action on the design input.

As shown in fig. 4, display interfaces of design inputs and design outputs are exemplified, for example, the display interfaces of the design inputs include a tube 1 thickness t1, a tube 2 wall thickness t2, a pump connection tube thickness tjg1, a pump support thickness tzc1, a pump support outer diameter Φ b1, a pump support compensator outer diameter Φ bc1, a pump support diameter flow path Φ b4, a pump support drop path width wdn, an operating level elevation Hbg7, an IHX and X axis angle α 1, an IHX and pump angle α 2, a main vessel inner diameter Φ essel, an in-stack support upper plate elevation Hbg4, a stack top stationary shield upper plane elevation Hbg9, a pump support cooling rise path width wup, and a pump-IHX center circle diameter Φ device 1. The display interface of the design output may include pump support and IHX-DHX support apparatus mounting surface elevation Hbg14, pump support compensator outer diameter Φ bc1, pump support diameter in-flow Φ b 4.

The operator can input the modification operation through the dialog box, for example, the values of t1, t2, tjg1, tzc1, Φ b1, Φ bc1, Φ b4, wdn, Hbg7, α 1, α 2, Φ mvessel, Hbg4, Hbg9, wup, Φ device 1, etc. are input in the column of "design input" of the dialog box, it is understood that the design output is related to the design input, and when the design input is changed, the data of the design output is also changed, and the design output indicates the physical structure parameters of the pump support, and when the operator inputs the corresponding data in the column of "design input", the operator indicates that the modification operation on the physical structure parameters of the three-dimensional model of the pump support is performed, and after inputting the corresponding data, the operator can determine the modification operation by clicking the "ok" button in the dialog box.

Step S206: and adjusting the physical structure of the corresponding sub three-dimensional model according to the modification operation.

Taking the sub three-dimensional model corresponding to the pump support as an example, when the values of t1, t2, tjg1, tzc1, Φ b1, Φ bc1, Φ b4, wdn, Hbg7, α 1, α 2, Φ mvessel, Hbg4, Hbg9, wup, Φ device 1, etc. are inputted in the column "design input" of the dialog box, the data of "design output" of the pump support is changed accordingly, and the physical structure of the corresponding sub three-dimensional model can be adjusted based on the changed data of "design output". In other embodiments of the present application, the operator may directly input the "design output" so as to adjust the physical structure of the corresponding sub three-dimensional model, i.e., adjust the pump support and IHX-DHX support apparatus mounting surface elevation Hbg14, the pump support compensator outer diameter Φ bc1, the pump support diameter flow channel Φ b4, etc., directly according to the input "design output" data.

Step S208: and assembling the sub three-dimensional model with the adjusted physical structure and other sub three-dimensional models of the preset reactor to construct a three-dimensional model of the reactor.

Taking the sub three-dimensional model corresponding to the pump support as an example, the sub three-dimensional model corresponding to the pump support with the adjusted physical structure is assembled with other sub three-dimensional models of a preset reactor, such as a sub three-dimensional model corresponding to a reactor vessel, a sub three-dimensional model corresponding to a reactor core, and the like, so as to construct a three-dimensional model of the reactor. It is understood that the above embodiment is exemplified by the pump supporting the corresponding sub-three-dimensional model, and in other embodiments, the above process may be applied to the sub-three-dimensional models corresponding to other structures of the reactor, or may be applied to a plurality of or all of the sub-three-dimensional models at the same time, that is, all the sub-three-dimensional models after the physical structures are adjusted may be assembled to construct the three-dimensional model of the reactor.

The construction method of the nuclear reactor, provided by the embodiment of the application, can enable designers of the nuclear reactor to quickly complete scheme design of the nuclear reactor, so that the design process of the reactor is relatively simplified, design experience and design method are streamlined, the design efficiency of the reactor is improved, screening, comparison, decision and the like in the scheme making stage of the nuclear reactor are facilitated, the work type with higher technical requirements can be made by the scheme, the work type with low dependence on personnel is converted, the automation level of the work type is improved, and personnel configuration of key technical posts can be saved. And the preset three-dimensional model of the reactor can be made by designers with abundant experience, so that the designers can fully inherit the experience knowledge of the designers with abundant experience in the process of using the construction method of the nuclear reactor.

In some embodiments of the present application, before the step of controlling the three-dimensional modeling software to output the preset three-dimensional model of the reactor, the method further includes: and acquiring a selection instruction, wherein the selection instruction instructs to select a three-dimensional model of a preset reactor from the constructed three-dimensional models of the multiple reactors. Accordingly, the step of controlling the three-dimensional modeling software to output the three-dimensional model of the predetermined reactor may include: and controlling the three-dimensional modeling software to output a three-dimensional model of the preset reactor according to the selection instruction.

That is to say, the reactor three-dimensional model building method can have a plurality of reactor three-dimensional models, and when a designer of the reactor receives a design task, the designer of the reactor can select a proper preset reactor three-dimensional model according to the design task, so that the corresponding design task is completed quickly, the application range of the nuclear reactor building method is widened, and the use experience of the designer is improved.

Before the step of adjusting the physical structure of the corresponding sub-three-dimensional model according to the modification operation, the method for constructing the reactor further includes: a first correspondence between the plurality of physical structure data of at least one of the sub-three-dimensional models is obtained. Accordingly, the step of adjusting the physical structure of the corresponding sub-three-dimensional model according to the modification operation may include: and adjusting at least one physical structure data of the corresponding sub three-dimensional model according to the at least one physical structure parameter, and adjusting other physical structure data of the corresponding sub three-dimensional model according to the first corresponding relation.

The first corresponding relation may be some calculation formulas, or some program calculation procedures judged by a loop algorithm. It can be understood that, when some physical structure data of a sub three-dimensional model is adjusted, other physical structure data of the sub three-dimensional model may also need to be adjusted, and the first corresponding relationship is just established, and the operation of the designer can be simplified through the above operation steps, and the efficiency of the design is improved.

In some embodiments of the present application, the selection instruction further instructs to select the first correspondence from a plurality of preset correspondences. That is, when the user selects the three-dimensional model of the predetermined reactor, the first correspondence relationship is simultaneously selected. That is, the three-dimensional model of each reactor may be encapsulated with the first corresponding relationship, such as the calculation formula, to form templates, and the designer may quickly complete the corresponding design task by calling the templates.

Before the step of adjusting the physical structure of the corresponding sub-three-dimensional model according to the modification operation, the method for constructing the three-dimensional model of the reactor may further include: and acquiring a second corresponding relation between a plurality of physical structure data of at least one sub three-dimensional model and a plurality of physical structure data of other sub three-dimensional models. Accordingly, the step of adjusting the physical structure of the corresponding sub-three-dimensional model according to the modification operation may include: and adjusting at least one physical structure data of the corresponding sub three-dimensional model according to the at least one physical structure parameter, and adjusting a plurality of physical structure data of other sub three-dimensional models according to the second corresponding relation.

It can be understood that there are some mutual matching relations between the components of the reactor, for example, the pump support is arranged in the main container, and the size of the inner diameter of the main container has an influence on the physical structure data of the pump support, that is, part of the data of the "design input" of the pump support is the data transmitted by other templates (corresponding to the main container), and the physical structure parameters of the pump support can be adjusted adaptively after the inner diameter of the main container is adjusted by the above method, thereby improving the efficiency of the design.

In some embodiments of the present application, the step of obtaining a modification operation on at least one physical structure parameter of at least one of the sub-three-dimensional models may include: a modification operation of at least one physical structure parameter of the plurality of sub-three-dimensional models is obtained. Correspondingly, the step of adjusting the physical structure of the corresponding sub-three-dimensional model according to the modification operation comprises: and sequentially adjusting the physical structures of the plurality of sub three-dimensional models according to the modification operation in a preset sequence. That is, after adjusting one sub-three-dimensional model, the adjustment of the next sub-three-dimensional model is automatically started according to the preset sequence, wherein the preset sequence may be set by the designer. Therefore, the automation level of the construction process of the three-dimensional model of the reactor is improved, and the efficiency is improved.

The plurality of sub three-dimensional models may include a first sub three-dimensional model adjusted first in a preset order and a second sub three-dimensional model adjusted last in the preset order, and the second correspondence relationship indicates that part of physical structure data of the second sub three-dimensional model is determined by the first sub three-dimensional model after the physical structure is adjusted. Accordingly, the step of sequentially adjusting the physical structures of the plurality of sub-three-dimensional models in a preset order according to the modification operation may include: and adjusting the physical structure of the second sub three-dimensional model according to the first sub three-dimensional model after the physical structure is adjusted.

FIG. 5 is a schematic illustration of a three-dimensional model of a stack container, a shield assembly, and a pump support assembly prior to adjustment according to one embodiment of the present application; FIG. 6 is a schematic view of a three-dimensional model of a stack container, a shield assembly, and a pump support assembly after adjustment, according to one embodiment of the present application. As shown in fig. 5 and 6, for example, the first sub-three-dimensional model may be a three-dimensional model of the stack container 20, and the second sub-three-dimensional model may be a three-dimensional model of the pump support 80, wherein fig. 5 and 6 also illustrate a three-dimensional model of the shield assembly 10. As can be seen from fig. 5 and 6, the physical structure parameters of the stack 20 have an influence on the physical structure parameters of the pump support 80, but in the embodiment of the present application, the three-dimensional model of the pump support 80 may be adjusted according to the three-dimensional model of the stack 20 after the physical structure is adjusted, for example, when the inner diameter Φ mvessel of the main vessel becomes smaller, the physical structure parameters of the pump support 80 in the corresponding dimension also become smaller, and the design output data corresponding to the main vessel 20 may be transmitted to the design input data corresponding to the pump support 80. Therefore, the automation level of the construction process of the three-dimensional model of the reactor is improved, and the efficiency is improved.

In some embodiments, the step of obtaining a modification operation on at least one physical structure parameter of at least one of the sub three-dimensional models and the step of adjusting the physical structure of the corresponding sub three-dimensional model according to the modification operation may be repeated a plurality of times, and each time the corresponding at least one sub three-dimensional model is executed differently. For example, the modification operation of the physical structure parameters of the sub three-dimensional model corresponding to the main container is obtained, the physical structure of the sub three-dimensional model corresponding to the main container is adjusted according to the modification operation, the modification operation of the physical structure parameters of the sub three-dimensional model corresponding to the pump is obtained, the physical structure of the sub three-dimensional model corresponding to the pump support is adjusted according to the modification operation, and then the sub three-dimensional model after the physical structure is assembled and adjusted is combined with other sub three-dimensional models of the preset reactor, so that the adjustment of the plurality of sub three-dimensional models is completed under the condition of simplifying the assembly operation.

Before the step of controlling the three-dimensional modeling software to output the preset three-dimensional model of the reactor, the method for constructing the three-dimensional model of the reactor may further include: acquiring indication information indicating information of the at least one sub three-dimensional model included in each execution. Correspondingly, each time the step of obtaining the modification operation of the at least one physical structure parameter of the at least one sub three-dimensional model, the at least one sub three-dimensional model is determined by the indication information. That is to say, the indication information indicates which sub-three-dimensional model specifically corresponds to each execution, and data or models and the like which need to be referred to each execution can be determined, so that preliminary task decomposition, division of labor and other operations can be performed in advance, the process of the construction process of the three-dimensional model of the reactor is clear, and the efficiency is improved.

In some embodiments, after the step of obtaining the indication information, the method of constructing a three-dimensional model of a reactor may further include: judging whether the output personnel of the indication information has corresponding authority; and if the judgment result is yes, in the step of acquiring the modification operation on the at least one physical structure parameter of the at least one sub three-dimensional model each time, the at least one sub three-dimensional model is determined by the indication information. The personnel with the corresponding authority can be professional designers with abundant experience, and the specific judgment process can be various modes such as face recognition, password recognition, fingerprint recognition and the like, so that the safety of the construction process of the three-dimensional model of the reactor can be ensured, and the occurrence of the situations of errors and the like caused by operations such as task decomposition, division of labor and the like due to malicious behaviors or unintentional behaviors can be avoided.

If the judgment result is negative, namely the output person of the indication information is judged not to have the corresponding authority, the signal output device is controlled to output the first prompt information, and the first prompt information indicates that the output person of the indication information does not have the corresponding authority. The signal output device can be a character image output device, a voice output device and the like, and in such a way, the personnel sending the indication information can know the related information, and the condition that the personnel sending the indication information mistakenly thinks that the indication information has influence on the construction process of the three-dimensional model of the reactor is avoided.

The indication information may also indicate requirements for the at least one sub-three-dimensional model included per execution, i.e. the indication information may indicate technical requirements of the issuing person of the indication information, which may be for example size requirements, structural strength requirements, etc. The indication information may also indicate data related to the at least one sub three-dimensional model included at each execution, which is expected to be output, that is, the indication information may indicate data indicating an output that a person who issues the indication information wishes to obtain, which may be, for example, "design output" mentioned above, or the like.

In some embodiments, before the step of controlling the three-dimensional modeling software to output the preset three-dimensional model of the reactor, the method for constructing the three-dimensional model of the reactor may further include: and judging whether a starting instruction is obtained or not, wherein the starting instruction indicates to start the operation of constructing the three-dimensional model of the reactor. And if the starting instruction is acquired, executing a step of controlling the three-dimensional modeling software to output a three-dimensional model of the preset reactor. The step of judging whether the starting instruction is acquired or not may be performed after the step of acquiring the instruction information, that is, the step of controlling the three-dimensional modeling software to output the three-dimensional model of the preset reactor is not performed immediately after the instruction information is acquired, but the step of controlling the three-dimensional modeling software to output the three-dimensional model of the preset reactor is performed only when the starting instruction is acquired, so that management of the process of the method for constructing the three-dimensional model of the reactor is facilitated.

If the starting instruction is not acquired, when the modification operation on at least one physical structure parameter of at least one sub three-dimensional model is acquired, controlling the signal output device to output second prompt information, wherein the second prompt information indicates that the starting instruction is not acquired. The signal output device can be a character image output device, a voice output device and the like, and by means of the method, a designer can know the reason why the construction process of the three-dimensional model of the reactor cannot be completed, and the use experience of the designer is improved.

If the starting instruction is obtained, before the step of controlling the three-dimensional modeling software to output the preset three-dimensional model of the reactor is executed, the method for constructing the three-dimensional model of the reactor may further include: judging whether the output personnel of the starting instruction has the corresponding authority; and if the output personnel of the starting instruction has the corresponding authority, executing a step of controlling the three-dimensional modeling software to output a three-dimensional model of the preset reactor. The personnel with the corresponding authority can be a design management department of the project of the construction of the three-dimensional model of the reactor, and understandably, the creation of the project of the construction of the three-dimensional model of the reactor and the introduction of the design process can be finished by the design management department. By the method, the safety of the construction process of the three-dimensional model of the reactor can be ensured, and the conditions that malicious behaviors or unintentional behaviors are directly started in the construction process of the three-dimensional model of the reactor and the like are avoided.

And if the output personnel of the starting instruction do not have the corresponding authority, controlling the signal output device to output third prompt information, wherein the third prompt information indicates that the output personnel of the starting instruction do not have the corresponding authority. The signal output device can be a character image output device, a voice output device and the like, and in such a way, the output personnel of the starting instruction can know the reason why the construction process of the three-dimensional model of the reactor cannot be completed, and the use experience of the output personnel of the starting instruction is improved.

In some embodiments, the method of constructing a three-dimensional model of a reactor may further comprise: acquiring character information and a sub three-dimensional model corresponding to the character information; and establishing a mapping relation between the character information and the sub three-dimensional model, wherein the mapping relation is used for displaying the character information when a viewing instruction of the sub three-dimensional model is obtained. For example, the designer may enter character information in the part name of the above dialog box, so that the sub-three-dimensional model corresponding to the pump support corresponds to the character information, thereby facilitating various operations such as search, viewing, and the like of the designer at a later date.

The embodiment of the application also provides a construction system of a three-dimensional model of a reactor, which comprises a controller, wherein the controller comprises a memory and a processor, a control program is stored in the memory, and the control program is used for realizing any construction method when being executed by the processor.

The construction method and the system of the nuclear reactor, provided by the embodiment of the application, can enable designers of the nuclear reactor to quickly complete scheme design of the nuclear reactor, enable the design process of the reactor to be relatively simplified, enable design experience and design method to be streamlined, improve the design efficiency of the reactor, facilitate screening, comparison, decision and the like in the scheme making stage of the nuclear reactor, enable the scheme making work with higher technical requirements to be converted into work with low dependence on personnel, improve the automation level of the work, and save personnel configuration of key technical posts. And the preset three-dimensional model of the reactor can be made by designers with abundant experience, so that the reactor layout, scheme design experience, method and algorithm can be established as a mathematical model, and the mathematical model is integrated and packaged into a system by combining software templates such as CATIA (computer-graphics aided three-dimensional interactive application) and the like, so that the design experience and the design method are streamlined, and the experience knowledge of the designers with abundant experience can be fully inherited by the designers in the process of using the construction method and the system of the nuclear reactor.

By taking the design of the scheme of the demonstration fast reactor body as an example, the construction system provided by the embodiment of the application is adopted, wherein 55 templates can be integrally packaged, 1273 related parameters can be input by a primary designer within 10 minutes through initial design and input parameters and a plurality of mouse clicks to complete the establishment of a three-dimensional model of the reactor body, the three-dimensional model can select different technical routes, in the technical route selection, the scheme of the three-dimensional model can select different loops, different relative height positions of sodium liquid and a reactor container, different elevator schemes and the like, for example, two loops or three loops can be selected for arrangement, a loading and unloading elevator can adopt a straight pull type or an inclined type, the sodium liquid level in the reactor container can be arranged on the top cover of the reactor container, and can also be arranged on the cylinder of the reactor container. The construction method and the construction system provided by the embodiment of the application have important guiding significance for fast reactor model design, fast completion of a three-dimensional design scheme of a reactor body and decision of a total scheme.

For the embodiments of the present application, it should also be noted that, in a case of no conflict, the embodiments of the present application and features of the embodiments may be combined with each other to obtain a new embodiment.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and the scope of the present application shall be subject to the scope of the claims.

Claims (19)

1. A method for constructing a three-dimensional model of a reactor, comprising: controlling the three-dimensional modeling software to output a three-dimensional model of a preset reactor, where the three-dimensional model of the preset reactor is composed of a sub-three-dimensional model assembly of at least one component of the preset reactor; acquiring a modification operation on at least one physical structure parameter of at least one of the sub-three-dimensional models; Adjust the physical structure of the corresponding sub-3D model according to the modification operation; The sub three-dimensional model after adjusting the physical structure is assembled, and the other sub three-dimensional models of the preset reactor are assembled to construct a three-dimensional model of the reactor. 2. The construction method according to claim 1, wherein, Before the step of controlling the three-dimensional modeling software to output the three-dimensional model of the preset reactor, the step further includes: acquiring a selection instruction, the selection instruction instructing to select the three-dimensional model of the preset reactor from the three-dimensional models of the multiple reactors that have been constructed ; The step of controlling the three-dimensional modeling software to output the three-dimensional model of the preset reactor includes: controlling the three-dimensional modeling software to output the three-dimensional model of the preset reactor according to the selection instruction. 3. The construction method according to claim 2, wherein, Before the step of adjusting the physical structure of the corresponding three-dimensional sub-model according to the modification operation, the step further includes: acquiring a first correspondence between a plurality of physical structure data of the at least one three-dimensional sub-model; The step of adjusting the physical structure of the corresponding sub-3D model according to the modification operation includes: adjusting at least one physical structure data of the corresponding sub-3D model according to the at least one physical structure parameter, and The first correspondence adjusts other physical structure data of the corresponding sub-3D model. 4. The construction method according to claim 3, wherein, The selection instruction further instructs to select the first correspondence from a plurality of preset correspondences. 5. The construction method according to claim 1, wherein, Before the step of adjusting the physical structure of the corresponding three-dimensional sub-model according to the modification operation, the step further includes: acquiring a plurality of physical structure data of the at least one three-dimensional sub-model, and other three-dimensional sub-models The second correspondence between the plurality of physical structure data of ; The step of adjusting the physical structure of the corresponding sub-3D model according to the modification operation includes: adjusting at least one physical structure data of the corresponding sub-3D model according to the at least one physical structure parameter, and The second correspondence adjusts a plurality of physical structure data of the other sub-3D models. 6. The construction method according to claim 5, wherein, The step of acquiring a modification operation for at least one physical structure parameter of at least one of the three-dimensional sub-models includes: acquiring a modification operation for at least one physical structure parameter of a plurality of sub-three-dimensional models; The step of adjusting the physical structures of the corresponding three-dimensional sub-models according to the modification operation includes: sequentially adjusting the physical structures of the plurality of three-dimensional sub-models in a preset order according to the modification operation. 7. The construction method according to claim 6, wherein, The plurality of sub-3D models include a first sub-3D model adjusted first in the preset order and a second sub-3D model adjusted later in the preset order, and the second correspondence indicates the second sub-3D model Part of the physical structure data of the three-dimensional model is determined by the first sub-three-dimensional model after adjusting the physical structure; The step of sequentially adjusting the physical structures of the multiple three-dimensional sub-models in a preset order according to the modification operation includes: further adjusting the physical structures of the second three-dimensional sub-models according to the first three-dimensional sub-models after adjusting the physical structures. physical structure. 8. The construction method according to claim 1, wherein, The step of acquiring a modification operation for at least one physical structure parameter of at least one of the three-dimensional sub-models, and the step of adjusting the physical structure of the corresponding three-dimensional sub-model according to the modification operation is repeated multiple times, and The at least one sub-three-dimensional model corresponding to each execution is different. 9. The construction method according to claim 8, wherein, Before the step of controlling the three-dimensional modeling software to output the three-dimensional model of the preset reactor, the method further includes: acquiring instruction information, the instruction information indicating the information of the at least one sub-three-dimensional model included in each execution; In each step of acquiring a modification operation on at least one physical structure parameter of the at least one sub-3D model, the at least one sub-3D model is determined by the indication information. 10. The construction method according to claim 9, wherein, After the step of obtaining the instruction information, the method further includes: judging whether the output person of the instruction information has the corresponding authority; If the result of the judgment is yes, in each step of acquiring a modification operation for at least one physical structure parameter of the at least one sub-3D model, the at least one sub-3D model is determined by the indication information Sure. 11. The construction method according to claim 10, wherein, If the result of the judgment is no, the control signal output device outputs first prompt information, and the first prompt information indicates that the person who outputs the instruction information does not have the corresponding authority. 12. The construction method according to claim 9, wherein, The indication information also indicates a requirement for the at least one of the sub-three-dimensional models included in each execution. 13. The construction method according to claim 9, wherein, The indication information further indicates data related to the at least one of the sub-three-dimensional models included in each execution that is expected to be output. 14. The construction method of claim 1, wherein, Before the step of controlling the three-dimensional modeling software to output the three-dimensional model of the preset reactor, the step further includes: judging whether a start-up instruction is obtained, the start-up instruction instructing to start the operation of constructing the three-dimensional model of the reactor; If the startup instruction is acquired, the step of controlling the three-dimensional modeling software to output the three-dimensional model of the preset reactor is performed. 15. The construction method of claim 14, wherein, If the startup instruction is not obtained, when the modification operation for at least one physical structure parameter of at least one of the three-dimensional sub-models is obtained, the control signal output device outputs second prompt information, the second prompt information indicates that the The startup instruction is obtained. 16. The construction method of claim 14, wherein, If the startup instruction is obtained, before executing the step of controlling the three-dimensional modeling software to output the three-dimensional model of the preset reactor, the method further includes: judging whether the person who outputs the startup instruction has the corresponding authority; If the person who outputs the startup instruction has the corresponding authority, the step of controlling the three-dimensional modeling software to output the three-dimensional model of the preset reactor is performed. 17. The construction method of claim 16, wherein, If the person who outputs the start instruction does not have the corresponding authority, the control signal output device outputs third prompt information, and the third prompt information indicates that the person who outputs the start instruction does not have the corresponding authority. 18. The construction method of claim 1 , further comprising: acquiring character information and the sub-three-dimensional model corresponding to the character information; A mapping relationship is established between the character information and the child three-dimensional model, and the mapping relationship is used to display the character information when a viewing instruction for the child three-dimensional model is obtained. 19. A system for constructing a three-dimensional model of a reactor, comprising: A controller, the controller includes a memory and a processor, the memory stores a control program, and when the control program is executed by the processor, it is used to implement the method according to any one of claims 1 to 18. build method.

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