CN112364416A - Design method and system of nuclear power station door meter - Google Patents
Design method and system of nuclear power station door meter Download PDFInfo
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- CN112364416A CN112364416A CN202011174904.8A CN202011174904A CN112364416A CN 112364416 A CN112364416 A CN 112364416A CN 202011174904 A CN202011174904 A CN 202011174904A CN 112364416 A CN112364416 A CN 112364416A
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Abstract
The invention provides a design method of a nuclear power station door watch, which comprises the following steps: creating a door opening cube, and extracting door parameter information according to the door opening cube; analyzing the function requirements of the door body, and obtaining attribute categories corresponding to the function requirements; performing logic judgment on the attribute type to acquire function combination information of the door body; generating a three-dimensional door model and an opening space according to the door parameter information and the function combination information; and outputting the door watch through the three-dimensional door model. The invention further provides a design system of the nuclear power station door meter. According to the design method and the system of the nuclear power station door meter, the automatic three-dimensional modeling of the door body is adopted, the automatic operation output of the functional principle of the door body is realized, and the workload is reduced.
Description
[ technical field ] A method for producing a semiconductor device
The invention relates to the technical field of door meters, in particular to a design method and a system of a nuclear power station door meter.
[ background of the invention ]
In the industrial engineering design of nuclear power and the like, a published door list needs to be designed for door purchase. Usually, the door list needs to contain the information as shown in fig. 1, and the door list design workload is very large due to the complicated data category of the carding and the technical analysis related to the fields with different dimensions.
The technical scheme includes that the method comprises the steps of firstly combing various data information one by one to form an initial list, and then showing the functional information of a door in a two-dimensional plant layout diagram to check the rationality of functional configuration and optimize the adaptability. And then, according to the size, the opening direction information and the function type of the door, three-dimensional modeling of the door is carried out, the feasibility of the installation and opening space of the door is checked, the arrangement scheme of the installation and opening area of the door is optimized, and the limitation requirement of the door rabbet is given by combining the installation condition. And finally, perfecting the two-dimensional information to form a final door list.
However, in the prior art, two-dimensional data combing and three-dimensional modeling of the door are two independent works, and the workload is large. After the two-dimensional data is changed, the three-dimensional model information cannot be updated synchronously. After the three-dimensional modeling finds a problem, not only the two-dimensional data needs to be adjusted, but also the three-dimensional model needs to be maintained again. And the function type selection of the door is to perform independent analysis according to each single dimension, the compatibility problem among different dimension functions needs to be gradually identified and eliminated in the design of subsequent links, the design steps are complicated, and the risk of human omission is high. When the function type selection principle is modified, all design flows need to be renewed.
In view of the above, it is desirable to provide a new design method and system for a nuclear power plant door table to overcome the above-mentioned drawbacks.
[ summary of the invention ]
The invention aims to: the design method and the system for the nuclear power station door meter have the advantages that automatic operation output of the functional principle of the door body is realized through automatic three-dimensional modeling of the door body, and workload is reduced.
In order to achieve the above object, in a first aspect, the present invention provides a method for designing a nuclear power plant door table, including the following steps: creating a door opening cube, and extracting door parameter information according to the door opening cube; analyzing the function requirements of the door body, and obtaining attribute categories corresponding to the function requirements; performing logic judgment on the attribute type to acquire function combination information of the door body; generating a three-dimensional door model and an opening space according to the door parameter information and the function combination information; and outputting the door watch through the three-dimensional door model.
In a preferred embodiment, the step of creating a door opening cube and extracting door body parameter information according to the door opening cube includes the following steps: defining diagonal corner point information of one face of the door opening cube; and acquiring the parameter information of the door body according to the diagonal corner information.
In a preferred embodiment, the step of creating a door opening cube and extracting door body parameter information according to the door opening cube includes the following steps: room coding information on two sides of the door body is obtained by extending the door opening cube to two sides; and extending downwards through the door opening cube to obtain the mounting structure layer of the door body and the height information of the finished surface.
In a preferred embodiment, the step of creating a door opening cube and extracting door body parameter information according to the door opening cube includes the following steps: after the door opening cube is created, an initial door body model is generated; detecting the rationality of the initial door body model; and when the initial door body model is unreasonable in design, sending out error-reporting prompt information.
In a preferred embodiment, the step of performing logic determination on the attribute type and acquiring the function combination information of the door body includes the steps of: performing single logic judgment on the attribute category corresponding to each function requirement to determine a preliminary function category; performing comprehensive logic judgment on the plurality of preliminary function categories according to compatibility requirements among the plurality of preliminary function categories; and outputting the finally required function combination information according to the comprehensive logic judgment result.
In a preferred embodiment, the step of generating a three-dimensional door model and an opening space according to the door parameter information and the function combination information includes the following steps: carrying out interference detection on the three-dimensional door body model and the opening space; and sending out error-reporting prompt information when the three-dimensional door model and the opening space interfere with surrounding items.
In a preferred embodiment, the step of sending an error notification message when the three-dimensional door model and the opening space interfere with surrounding items includes the following steps: when the interference is tongue-and-groove interference, sending out prompt information for modifying the tongue-and-groove size; and when the interference is opening interference, sending out prompt information for adjusting the interference item.
In a preferred embodiment, the door parameter information includes size information, positioning information, and opening direction information.
In a preferred embodiment, the functional requirements include shielding requirements, air tightness requirements, fire protection requirements, thermal insulation requirements, and sound insulation requirements.
In a second aspect, the invention further provides a design system of a nuclear power station door table, which comprises a creating module, an analyzing module, a judging module, a generating module and an output module; the creating module is used for creating a door opening cube and extracting door body parameter information according to the door opening cube; the analysis module is used for analyzing the functional requirements of the door body and obtaining the attribute category corresponding to each functional requirement; the judging module is used for logically judging the attribute type to acquire the function combination information of the door body; the generating module is used for generating a three-dimensional door body model and opening a virtual space according to the door body parameter information and the function combination information; the output module is used for outputting a door table through the three-dimensional door model.
Compared with the prior art, the design method and the system for the nuclear power station door table provided by the invention have the advantages that the door opening cube is created, door parameter information such as door size and opening direction can be extracted, and the associated elevation and room information on two sides can be automatically identified; the logic output of the gate function design can be realized, and other function information output can be expanded based on the logic output; moreover, problems such as unreasonable functions, collision and the like in the design process can give error-reporting prompts in the first time, so that designers can be helped to check the problems early and comprehensively, the design quality is better guaranteed, and the workload is greatly reduced.
In order to make the aforementioned and other objects, features and advantages of the present invention comprehensible, preferred embodiments accompanied with figures are described in detail below.
[ description of the drawings ]
In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.
FIG. 1 is a prior art information category diagram of a portal list;
FIG. 2 is a schematic block diagram of a design system for a nuclear power plant door table according to the present invention;
FIG. 3 is a flow chart of a design method of a nuclear power plant door table according to the present invention;
FIG. 4 is a flow chart illustrating the sub-steps of step S30 of the design method of the nuclear power plant door table according to the present invention;
fig. 5 is a logic decision flowchart of the airtight function requirement and the shielding function requirement of the design method of the nuclear power plant door table provided by the invention.
[ detailed description ] embodiments
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without making any creative effort, shall fall within the protection scope of the present invention.
Please refer to fig. 2, which is a schematic block diagram of a design system 100 for a nuclear power plant door table according to the present invention. The design system 100 of the nuclear power plant door table provided by the invention comprises a creation module 10, an analysis module 20, a judgment module 30, a generation module 40 and an output module 50.
The creating module 10 is used for creating a door opening cube and extracting door body parameter information according to the door opening cube; the analysis module 20 is configured to analyze the functional requirements of the door body, and obtain an attribute category corresponding to each functional requirement; the judging module 30 is configured to perform logic judgment on the attribute categories to obtain function combination information of the door body; the generating module 40 is configured to generate a three-dimensional door model and open a virtual space according to the door parameter information and the function combination information; the output module 50 is used for outputting a door table through the three-dimensional door model.
It will be appreciated that the configuration shown in FIG. 2 is merely illustrative and that the nuclear power plant door table design system 100 may include more or fewer components than shown in FIG. 2 or may have a different configuration than shown in FIG. 2. The components shown in fig. 2 may be implemented in hardware, software, or a combination thereof.
The functional modules described above will be described in detail with reference to fig. 3.
As shown in fig. 3, it is a flowchart of a design method of a nuclear power plant door table provided by the present invention. It should be noted that the method of the present invention is not limited to the order of the following steps, and in other embodiments, the method of the present invention may include only a portion of the following steps, or some of the steps may be deleted.
The design method of the nuclear power station door table provided by the invention comprises the following steps:
step S10: and creating a door opening cube, and extracting door body parameter information according to the door opening cube. Namely, with the aid of a three-dimensional model design platform, parameter information related to a door body structure is given at the beginning of door opening modeling, specifically, a door opening cube is created in a three-dimensional model, diagonal corner information of one surface of the door opening cube is defined, and the parameter information of the door body is obtained according to the diagonal corner information. It can be understood that the size information of the door opening cube is the net size of the door opening, the plane where the diagonal line is located is the direction where the tongue and groove is formed, and the side where the upper corner point is located is the door axis direction, so that the size information, the positioning information and the opening direction information of the door body can be obtained through datamation extraction parameters.
Further, room coding information on two sides of the door body is obtained by extending the door opening cube to two sides; through door opening cube extends downwards and acquires the mounting structure layer of the door body and the height information of the finished surface, so that the automatic identification of the associated elevation and the room information on two sides of the door opening cube can be realized.
Further, after the door opening cube is created, an initial door body model can be generated; detecting the rationality of the initial door body model; and when the initial door body model is unreasonable in design, sending out error-reporting prompt information. Specifically, the initial door body model contains initial general tongue-and-groove information for designers to preliminarily distinguish the rationality of the door body installation and opening space, and if the tongue-and-groove size in the initial door body model does not meet the design requirement, error reporting prompt information is sent to remind the designers to manually assign the tongue-and-groove size, so that the designers can be helped to investigate problems early, and the design quality can be better guaranteed.
Step S20: and analyzing the functional requirements of the door body, and obtaining the attribute type corresponding to each functional requirement. Specifically, various functional requirements are deeply analyzed, and finally, the functional requirements and the attribute types of the room attributes and the door opening positions form corresponding logical relations. Taking the shielding function requirement as an example, firstly, combing the logic association information whether a shielding door needs to be set, specifically considering the setting of a labyrinth wall, the radioactivity level attributes of rooms on two sides and the like; and then combing parameter information required by the calculation of the shielding thickness, wherein the relative distance between the door opening and the radioactive source, the radioactivity level attributes of rooms on two sides and the like are specifically required to be considered. It can be understood that the functional requirements further include airtight requirements, fireproof requirements, heat preservation requirements, sound insulation requirements and the like, and the same strategy is adopted for various other functional requirements so as to judge the attribute type to which each functional requirement belongs.
Step S30: and logically judging the attribute type to acquire the function combination information of the door body. Specifically, referring to fig. 4, step S30 includes the following sub-steps:
step S301: and performing single logic judgment on the attribute category corresponding to each function requirement, and determining a preliminary function category.
Step S302: and carrying out comprehensive logic judgment on the plurality of preliminary function categories according to the compatibility requirements among the plurality of preliminary function categories.
Step S303: and outputting the finally required function combination information according to the comprehensive logic judgment result.
It can be understood that according to the attribute category of the step S20, a preliminary function category is determined by the single logic determination module; and finally outputting the required function combination through a comprehensive logic judgment module by combining the compatibility requirements among the function categories. For example, when the semi-hermetic requirement is superimposed on the fire protection requirement, only the fire protection requirement is retained; when the shielding requirement is overlapped with the airtight requirement, an error is required to be reported to remind a designer to adjust the functional attributes of the room, so that the overlapping conflict of the two functions is avoided.
Please refer to fig. 5, which is a flow chart illustrating a logic determination of the airtight function requirement and the shielding function requirement. It is understood that the determination process for other functional requirement categories is similar and will not be described herein again.
Step S40: and generating a three-dimensional door model and an opening space according to the door parameter information and the function combination information. Further, after a three-dimensional door model and an opening space are generated, interference detection is carried out on the three-dimensional door model and the opening space; and sending out error-reporting prompt information when the three-dimensional door model and the opening space interfere with surrounding items. Specifically, when the interference is tongue-and-groove interference, prompt information for modifying the tongue-and-groove size is sent; when the interference is opening interference, prompt information for adjusting interference items is sent to remind designers of modifying the tongue-and-groove size or modifying the design, so that the interference problem of opening space is avoided.
Step S50: through the three-dimensional door model output door table, the door table is directly output through the three-dimensional door model, two-dimensional data carding is not needed in the door table design process, the compatibility problem among different dimensionality functions is not needed to be considered, automatic operation output of a functional principle of the door body is realized through automatic three-dimensional modeling of the door body, and the workload is reduced.
According to the design method of the nuclear power station door table, the complex door table design process is logically split and sorted, and the corresponding logical operation process is designed, so that a series of work such as door body modeling, door body collision inspection and the like can be completed while the door table information is designed through maintenance of some basic information; by means of the three-dimensional model design platform, parameter information related to the door body structure is given at the beginning of door opening modeling, and fault-reporting prompts can be given at the first time when problems such as unreasonable functions, collision and the like in the design process, so that designers can be helped to troubleshoot problems early and comprehensively, and the design quality is better guaranteed; corresponding logic function expansion can be conveniently carried out through platform data of a gate table design automation technology, so that information required by other design work is derived, and the workload is greatly reduced.
It should be noted that all the embodiments of the method for designing a nuclear power plant door table provided by the present invention are applicable to the system 100 for designing a nuclear power plant door table provided by the present invention, and all the embodiments can achieve the same or similar beneficial effects. It can be understood that the design method and the system of the door watch provided by the invention are not limited to be applied to the technical field of nuclear power, and can also be applied to the fields of thermal power and other complex engineering.
In summary, according to the design method and system 100 for the nuclear power plant door table provided by the invention, the door body parameter information such as the size and the opening direction of the door body can be extracted by creating the door opening cube, and the associated elevation and the room information on two sides can be automatically identified; the logic output of the gate function design can be realized, and other function information output can be expanded based on the logic output; moreover, problems such as unreasonable functions, collision and the like in the design process can give error-reporting prompts in the first time, so that designers can be helped to check the problems early and comprehensively, the design quality is better guaranteed, and the workload is greatly reduced.
The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes performed by the present specification and drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.
Claims (10)
1. A design method of a nuclear power station door table is characterized by comprising the following steps:
creating a door opening cube, and extracting door parameter information according to the door opening cube;
analyzing the function requirements of the door body, and obtaining attribute categories corresponding to the function requirements;
performing logic judgment on the attribute type to acquire function combination information of the door body;
generating a three-dimensional door model and an opening space according to the door parameter information and the function combination information;
and outputting the door watch through the three-dimensional door model.
2. The method for designing the nuclear power plant door table according to claim 1, wherein the step of creating a door opening cube and extracting door body parameter information according to the door opening cube comprises the following steps:
defining diagonal corner point information of one face of the door opening cube;
and acquiring the parameter information of the door body according to the diagonal corner information.
3. The method for designing the nuclear power plant door table according to claim 1, wherein the step of creating a door opening cube and extracting door body parameter information according to the door opening cube comprises the following steps:
room coding information on two sides of the door body is obtained by extending the door opening cube to two sides; and
and the mounting structure layer and the finished surface elevation information of the door body are obtained by extending the door opening cube downwards.
4. The method for designing the nuclear power plant door table according to claim 1, wherein the step of creating a door opening cube and extracting door body parameter information according to the door opening cube comprises the following steps:
after the door opening cube is created, an initial door body model is generated;
detecting the rationality of the initial door body model;
and when the initial door body model is unreasonable in design, sending out error-reporting prompt information.
5. The method for designing a nuclear power plant door table according to claim 1, wherein the step of performing logical judgment on the attribute type and acquiring the function combination information of the door body includes the steps of:
performing single logic judgment on the attribute category corresponding to each function requirement to determine a preliminary function category;
performing comprehensive logic judgment on the plurality of preliminary function categories according to compatibility requirements among the plurality of preliminary function categories;
and outputting the finally required function combination information according to the comprehensive logic judgment result.
6. The design method of the nuclear power plant door table according to claim 1, wherein the step of generating a three-dimensional door model and an opening space according to the door parameter information and the function combination information includes the steps of:
carrying out interference detection on the three-dimensional door body model and the opening space;
and sending out error-reporting prompt information when the three-dimensional door model and the opening space interfere with surrounding items.
7. The design method of the nuclear power plant door watch according to claim 6, wherein the step of sending an error-reporting prompt message when the three-dimensional door body model and the opening space interfere with surrounding items comprises the following steps:
when the interference is tongue-and-groove interference, sending out prompt information for modifying the tongue-and-groove size; and
and when the interference is opening interference, sending prompt information for adjusting the interference item.
8. The method of claim 1, wherein the door parameter information includes dimensional information, positioning information, and opening direction information.
9. The method of designing a nuclear power plant door watch as recited in claim 1, wherein the functional requirements include shielding requirements, air tightness requirements, fire protection requirements, thermal insulation requirements, and sound insulation requirements.
10. A design system of a nuclear power station door table is characterized by comprising a creation module, an analysis module, a judgment module, a generation module and an output module; the creating module is used for creating a door opening cube and extracting door body parameter information according to the door opening cube; the analysis module is used for analyzing the functional requirements of the door body and obtaining the attribute category corresponding to each functional requirement; the judging module is used for logically judging the attribute type to acquire the function combination information of the door body; the generating module is used for generating a three-dimensional door body model and opening a virtual space according to the door body parameter information and the function combination information; the output module is used for outputting a door table through the three-dimensional door model.
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