CN112836261A - House structure generation method and device, computer equipment and storage medium - Google Patents

Abstract

The application relates to a house structure generation method, a house structure generation device, computer equipment and a storage medium. The method comprises the following steps: acquiring a simulation wall of a design model; room marking is carried out on the simulation wall of the design model, and a component model for distinguishing the space of the design model is obtained; and acquiring the setting parameters corresponding to the component model, and generating the component model according to the setting parameters. By adopting the method, the generation efficiency and accuracy of the house structure can be improved.

Description

House structure generation method and device, computer equipment and storage medium

Technical Field

The present application relates to the field of building design technologies, and in particular, to a method and an apparatus for generating a house structure, a computer device, and a storage medium.

Background

With the rapid development of computer technology, automated aided design has been widely used in various industries.

Generally, in the field of building design, people use automated design software to design buildings. Generally, when designing a house model, a designer is required to manually draw components of a positioning structure, such as a beam, a column, a floor, etc., one by one according to design requirements and by combining his own experience.

However, the conventional design requires a lot of time and effort from the designer and has a low accuracy.

Disclosure of Invention

In view of the above, it is necessary to provide a house structure generation method, apparatus, computer device and storage medium capable of improving generation efficiency and accuracy.

In a first aspect, an embodiment of the present application provides a house structure generation method, where the method includes:

acquiring a simulation wall of a design model;

room marking is carried out on the simulation wall of the design model, and a component model for distinguishing the space of the design model is obtained;

and acquiring the setting parameters corresponding to the component model, and generating the component model according to the setting parameters.

In a second aspect, an embodiment of the present application provides a building structure generation method, where the method includes:

acquiring a simulation wall of a design model;

room marking is carried out on the simulation wall of the design model, and a component model for distinguishing the space of the design model is obtained; the component model comprises a column model, a beam model, a floor slab model and a roof model;

acquiring the section type of the column model, the section size of the column model and the material of the column model, which are input by a user, through a setting dialog box of the column model;

generating the column model according to the section type of the column model, the section size of the column model and the material of the column model;

acquiring the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated, which are input by a user, through a setting dialog box of the beam model;

generating the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated or not;

outputting prompt information on a parameter setting interface, wherein the prompt information is as follows: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof;

acquiring the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by a user through a setting dialog box of the floor model;

generating the floor model according to the floor type, the floor model, the floor thickness and the total plate thickness;

acquiring the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length of the roof model input by a user through a setting dialog box of the roof model;

and generating the roof model according to the type of the roof section, the beam section, the type of the purline, the specification of the purline, the material and the cornice length.

In a third aspect, an embodiment of the present application provides a building structure generation apparatus, where the apparatus includes:

the acquisition module is used for acquiring a simulation wall of the design model;

the marking module is used for marking rooms on the simulation wall of the design model to obtain a component model for distinguishing the space of the design model;

and the generating module is used for acquiring the setting parameters corresponding to the component model and generating the component model according to the setting parameters.

In a fourth aspect, an embodiment of the present application provides a building structure generation apparatus, including:

the acquisition module is used for acquiring a simulation wall of the design model;

the marking module is used for marking rooms on the simulation wall of the design model to obtain a component model for distinguishing the space of the design model; the component model comprises a column model, a beam model, a floor slab model and a roof model;

the first generation module is used for acquiring the section type of the column model, the section size of the column model and the material of the column model input by a user through a setting dialog box of the column model, and generating the column model according to the section type of the column model, the section size of the column model and the material of the column model;

the second generation module is used for acquiring the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated, which are input by a user, through a setting dialog box of the beam model; generating the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated or not, and outputting prompt information on a parameter setting interface, wherein the prompt information is as follows: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof;

the third generation module is used for acquiring the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by a user through a setting dialog box of the floor model, and generating the floor model according to the floor type, the floor model, the floor thickness and the total plate thickness;

and the fourth generation module is used for acquiring the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length of the roof model input by a user through a setting dialog box of the roof model, and generating the roof model according to the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length.

In a fifth aspect, an embodiment of the present application provides a computer device, including a memory and a processor, where the memory stores a computer program, and the processor implements the following steps when executing the computer program:

acquiring a simulation wall of a design model;

room marking is carried out on the simulation wall of the design model, and a component model for distinguishing the space of the design model is obtained;

and acquiring the setting parameters corresponding to the component model, and generating the component model according to the setting parameters.

In a sixth aspect, an embodiment of the present application provides a computer device, including a memory and a processor, where the memory stores a computer program, and the processor implements the following steps when executing the computer program:

acquiring a simulation wall of a design model;

room marking is carried out on the simulation wall of the design model, and a component model for distinguishing the space of the design model is obtained; the component model comprises a column model, a beam model, a floor slab model and a roof model;

acquiring the section type of the column model, the section size of the column model and the material of the column model, which are input by a user, through a setting dialog box of the column model;

generating the column model according to the section type of the column model, the section size of the column model and the material of the column model;

acquiring the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated, which are input by a user, through a setting dialog box of the beam model;

generating the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated or not;

outputting prompt information on a parameter setting interface, wherein the prompt information is as follows: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof;

acquiring the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by a user through a setting dialog box of the floor model;

generating the floor model according to the floor type, the floor model, the floor thickness and the total plate thickness;

acquiring the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length of the roof model input by a user through a setting dialog box of the roof model;

and generating the roof model according to the type of the roof section, the beam section, the type of the purline, the specification of the purline, the material and the cornice length.

In a seventh aspect, an embodiment of the present application provides a computer-readable storage medium, on which a computer program is stored, where the computer program, when executed by a processor, implements the following steps:

acquiring a simulation wall of a design model;

room marking is carried out on the simulation wall of the design model, and a component model for distinguishing the space of the design model is obtained;

and acquiring the setting parameters corresponding to the component model, and generating the component model according to the setting parameters.

In an eighth aspect, an embodiment of the present application provides a computer-readable storage medium, on which a computer program is stored, where the computer program, when executed by a processor, implements the following steps:

acquiring a simulation wall of a design model;

room marking is carried out on the simulation wall of the design model, and a component model for distinguishing the space of the design model is obtained; the component model comprises a column model, a beam model, a floor slab model and a roof model;

acquiring the section type of the column model, the section size of the column model and the material of the column model, which are input by a user, through a setting dialog box of the column model;

generating the column model according to the section type of the column model, the section size of the column model and the material of the column model;

acquiring the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated, which are input by a user, through a setting dialog box of the beam model;

generating the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated or not;

outputting prompt information on a parameter setting interface, wherein the prompt information is as follows: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof;

acquiring the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by a user through a setting dialog box of the floor model;

generating the floor model according to the floor type, the floor model, the floor thickness and the total plate thickness;

acquiring the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length of the roof model input by a user through a setting dialog box of the roof model;

and generating the roof model according to the type of the roof section, the beam section, the type of the purline, the specification of the purline, the material and the cornice length.

According to the house structure generation method, the house structure generation device, the computer equipment and the storage medium, the computer equipment obtains the component model for distinguishing the design model space by obtaining the simulation wall of the design model and marking the room of the simulation wall of the design model, so that the component model is automatically generated by obtaining the setting parameters corresponding to the component model and according to the setting parameters, and further the design model is automatically generated. The method avoids the problems of low efficiency and large errors caused by manually drawing the house structures one by one in the prior art, the component models are automatically generated through computer equipment, and then the house structures are generated, so that the workload and the generation difficulty of designers can be greatly reduced, the efficiency is greatly improved, the design time is further shortened, the design cost is reduced, and the accuracy of the house structure generation is also greatly improved. Meanwhile, the design threshold of designers is reduced, so that the designers can finish the generation of the house structure through simple operation, and the learning cost is greatly reduced.

Drawings

FIG. 1 is a diagram illustrating an internal structure of a computer device according to an embodiment;

fig. 2 is a schematic flow chart of a house structure generation method according to an embodiment;

FIG. 3 is a schematic diagram of a setting interface of setting parameters corresponding to a column model according to another embodiment;

FIG. 4 is a schematic view of a setting interface of setting parameters corresponding to a beam model according to yet another embodiment;

FIG. 5 is a schematic view of a setting interface of setting parameters corresponding to a floor model according to still another embodiment;

FIG. 6 is a schematic view of a setting interface of setting parameters corresponding to a roof model according to yet another embodiment;

fig. 7 is a schematic flowchart of a house structure generation method according to still another embodiment;

FIG. 8 is a schematic illustration of a housing structure of an upright flat roof of light steel construction produced according to one embodiment;

FIG. 9 is a plan view of the house model shown in FIG. 8;

fig. 10 is a schematic structural diagram of a house structure generation apparatus according to an embodiment;

fig. 11 is a schematic structural diagram of a house structure generation device according to another embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

The house structure generation method provided by the embodiment of the application can be applied to the computer equipment shown in fig. 1. The computer device comprises a processor, a memory, a network interface, a database, a display screen and an input device which are connected through a system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, a computer program, and a database. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The database of the computer device is used for storing the design models in the following embodiments, and the detailed description of the design models is provided in the following embodiments. The network interface of the computer device may be used to communicate with other devices outside over a network connection. Optionally, the computer device may be a server, a desktop, a personal digital assistant, other terminal devices such as a tablet computer, a mobile phone, and the like, or a cloud or a remote server, and the specific form of the computer device is not limited in the embodiment of the present application. The display screen of the computer equipment can be a liquid crystal display screen or an electronic ink display screen, and the input device of the computer equipment can be a touch layer covered on the display screen, a key, a track ball or a touch pad arranged on the shell of the computer equipment, an external keyboard, a touch pad or a mouse and the like. Of course, the input device and the display screen may not belong to a part of the computer device, and may be external devices of the computer device.

Those skilled in the art will appreciate that the architecture shown in fig. 1 is merely a block diagram of some of the structures associated with the disclosed aspects and is not intended to limit the computing devices to which the disclosed aspects apply, as particular computing devices may include more or less components than those shown, or may combine certain components, or have a different arrangement of components.

The following describes the technical solutions of the present application and how to solve the above technical problems with specific examples. The following several specific embodiments may be combined with each other, and details of the same or similar concepts or processes may not be repeated in some embodiments. Embodiments of the present application will be described below with reference to the accompanying drawings.

It should be noted that the execution subject of the method embodiments described below may be a building structure generation apparatus, which may be implemented as part of or all of the computer device described above by software, hardware, or a combination of software and hardware. The following method embodiments are described by taking the execution subject as the computer device as an example.

Fig. 2 is a schematic flow chart of a house structure generation method according to an embodiment. The embodiment relates to a specific process for automatically generating the house structure by the computer equipment according to the setting parameters. As shown in fig. 2, includes:

and S10, obtaining a simulation wall of the design model.

Specifically, the computer device may read a simulation wall of the design model, where the simulation wall is used to represent the distribution of the overall structure of the design model, but the simulation wall cannot represent actual attributes of the design model, such as the structure type and specification. The simulation wall may be a simulation wall drawn by a designer through a computer device, or a simulation wall automatically generated by a computer device to match a design requirement by automatically analyzing the design requirement.

And S20, marking a room on the simulation wall of the design model to obtain a component model for distinguishing the design model space.

Specifically, the computer device may mark a room on the simulation wall of the design model, for example, a designer marks the simulation wall through the computer device, or the computer device may automatically analyze the design requirement, so as to automatically perform room marking on the simulation wall, thereby obtaining a component model capable of distinguishing the space of the design model. Alternatively, the component model may include a plurality of types, and the simulated wall may include a plurality of types of walls, such as a simulated roof, a simulated floor, a simulated interior wall, and the like, which is not limited in this embodiment.

And S30, acquiring the setting parameters corresponding to the component model, and generating the component model according to the setting parameters.

Specifically, the computer device may obtain setting parameters of different component models, for example, the setting parameters may be set by receiving user input, or design requirements may be analyzed by the computer, so as to obtain the setting parameters of different component models, and then the component models are automatically generated according to the setting parameters of each component, and further, the automatic generation of the building structure is completed by generating the different component models. Alternatively, the computer device may calculate the model by selecting an automatic structure calculation mode in which the device pops up a dialog box through which the designer inputs design parameters, and then the computer device automatically generates different component models according to the set parameters. Alternatively, the computer device may determine the intersection relationship or the adjacent relationship between the component model to be generated and the other entity model according to the setting parameter, and then generate different component models according to the generation rules of the different component models. The rule is generated such that the position and direction of the component model, the adjacent relation and the intersecting relation satisfy the rule of the design specification, such as the rule of no collision.

In this embodiment, the computer device obtains the component model for distinguishing the design model space by obtaining the simulation wall of the design model and performing room marking on the simulation wall of the design model, so as to realize automatic generation of the component model by obtaining the setting parameters corresponding to the component model and according to the setting parameters, thereby realizing automatic generation of the design model. The method avoids the problems of low efficiency and large errors caused by manually drawing the house structures one by one in the prior art, the component models are automatically generated through computer equipment, and then the house structures are generated, so that the workload and the generation difficulty of designers can be greatly reduced, the efficiency is greatly improved, the design time is further shortened, the design cost is reduced, and the accuracy of the house structure generation is also greatly improved. Meanwhile, the design threshold of designers is reduced, so that the designers can finish the generation of the house structure through simple operation, and the learning cost is greatly reduced.

Optionally, the constructed model may include a column model, and one possible implementation manner of the step S30 may include: acquiring the section type of the column model, the section size of the column model and the material of the column model, which are input by a user, through a setting dialog box of the column model; and generating the column model according to the section type of the column model, the section size of the column model and the material of the column model. Specifically, the computer device may receive an instruction that the user clicks the "column" in the popped dialog box through the external device, and then receive corresponding setting parameters, such as a section type, a section size, a material, and the like of the column model, selected or input by the user in the dialog box of the tab page, and optionally, a setting interface of the setting parameters corresponding to the column model may be as shown in fig. 3. Then, the computer device may receive an instruction for completing the parameter input by the user, for example, the user clicks a "generation" button, and the column model is automatically generated according to the section type, the section size, and the material of the column model. Alternatively, the column model may include a plurality of column models, such as a composite column model, a reinforced column, and the like. In this embodiment, the computer device obtains the section type of the column model, the section size of the column model, and the material of the column model, which are input by the user, through the setting dialog box of the column model, and automatically generates the column model according to the section type of the column model, the section size of the column model, and the material of the column model, thereby greatly improving the generation efficiency and accuracy of the column model.

Optionally, the component model includes a beam model, and one possible implementation manner of the step S30 may include: acquiring the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated, which are input by a user, through a setting dialog box of the beam model; and generating the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated. Specifically, the computer device may receive an instruction that the user clicks the "beam" label in the pop-up dialog box through the external device, and then receive corresponding setting parameters selected or input by the user in the dialog box of the label page, such as a section type of the beam model, a section size of the beam model, a material of the beam model, whether the secondary beam is generated, and the like, and optionally, a setting interface of the setting parameters corresponding to the beam model may be as shown in fig. 4. Then, the computer device may receive an instruction for completing parameter input by the user, for example, the user clicks a "generation" button, and the beam model is automatically generated according to the section type of the beam model, the section size of the beam model, the material of the beam model, and whether the secondary beam is generated. Alternatively, the beam model may include a plurality of beam models, such as a combination lintel model, a top guide beam model, and a bottom guide beam model, and the like. In this embodiment, the computer device obtains the section type of the beam model, the section size of the beam model, the material of the beam model, and whether the secondary beam is generated, which are input by the user, through the setting dialog box of the beam model, and automatically generates the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model, and whether the secondary beam is generated, so that the generation efficiency and accuracy of the beam model are greatly improved.

Optionally, when the component model is a beam model, the method further comprises: outputting prompt information on a parameter setting interface, wherein the prompt information is as follows: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof. Through outputting the prompt information, the designer can be reminded, and therefore the accuracy of the generation of the beam model is further ensured.

Optionally, the component model includes a floor slab model, and another possible implementation manner of the step S30 may include: acquiring the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by a user through a setting dialog box of the floor model; and generating the floor slab model according to the floor slab type, the floor slab model, the floor slab thickness and the total plate thickness. Specifically, the computer device may receive an instruction that the user clicks the label "floor" in the popped dialog box through the external device, and then receive corresponding setting parameters, such as a floor type, a floor model, a floor thickness, a total plate thickness, and the like of the floor model, selected or input by the user in the dialog box of the label page, and optionally, a setting interface of the setting parameters corresponding to the floor model may be as shown in fig. 5. Then, the computer device may receive an instruction for completing parameter input by the user, for example, the user clicks a "generation" button, and automatically generates a floor model according to the floor type, the floor model, the floor thickness, and the total plate thickness of the floor model. Optionally, the floor model may include a plurality of floor models, and the present embodiment does not limit the types of the floor models. In this embodiment, the computer device obtains the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by the user through the setting dialog box of the floor model, and automatically generates the floor model according to the floor type, the floor model, the floor thickness and the total plate thickness, so that the generation efficiency and the accuracy of the floor model are greatly improved.

Optionally, the component model includes a roof model, and another possible implementation manner of the step S30 may include: acquiring the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length of the roof model input by a user through a setting dialog box of the roof model; and generating the roof model according to the type of the roof section, the beam section, the type of the purline, the specification of the purline, the material and the cornice length. Specifically, the computer device may receive an instruction that the user clicks the label "roof" in the pop-up dialog box through the external device, and then receive corresponding setting parameters, such as the type of the roof, the model of the roof, the thickness of the total panel, and the like, selected or input by the user in the dialog box of the label page, and optionally, a setting interface of the setting parameters corresponding to the roof model may be as shown in fig. 6. Then, the computer device may receive an instruction for completing parameter input by a user, for example, the user clicks a "generation" button, and the roof model is automatically generated according to the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length of the roof model. Alternatively, the roofing model may comprise a plurality of roofing models, such as a flat roofing model, a four-pitched roofing model, or the like. In this embodiment, the computer device obtains, through a dialog box for setting a roof model, a roof type, a roof model, a roof thickness, and a total board thickness of the roof model input by a user; according to the type of the roof, the thickness of the roof and the thickness of the total plate, the roof model is automatically generated according to the simulated roof, so that the generation efficiency and the accuracy of the roof model are greatly improved.

For more clear illustration of the solution provided by the embodiments of the present application, a detailed description is provided herein with a specific embodiment, as shown in fig. 7, including:

s71, obtaining a simulation wall of the design model;

s72, marking a room on the simulation wall of the design model to obtain a component model for distinguishing the space of the design model; the component model comprises a column model, a beam model, a floor slab model and a roof model;

s73, acquiring the section type of the column model, the section size of the column model and the material of the column model input by a user through a setting dialog box of the column model, and generating the column model according to the section type of the column model, the section size of the column model and the material of the column model;

s74, acquiring the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated, which are input by a user, through a setting dialog box of the beam model, generating the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model and whether the secondary beam is generated, and outputting prompt information on a parameter setting interface, wherein the prompt information is as follows: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof;

s75, acquiring the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by a user through a setting dialog box of the floor model, and generating the floor model according to the floor type, the floor model, the floor thickness and the total plate thickness;

s76, acquiring the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length of the roof model input by a user through a setting dialog box of the roof model, and generating the roof model according to the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length.

The implementation principle and technical effect in this embodiment may refer to the foregoing embodiments, and are not described herein again. Fig. 8 is a schematic view of a house structure of an upright flat roof of a light steel structure automatically generated by a computer device, and fig. 9 is a plan view of the house model shown in fig. 8. Of course, the method may also generate other house structures, and this embodiment is not limited thereto.

It should be understood that although the steps in the flowcharts of fig. 2 and 7 are shown in order as indicated by the arrows, the steps are not necessarily performed in order as indicated by the arrows. The steps are not performed in the exact order shown and described, and may be performed in other orders, unless explicitly stated otherwise. Moreover, at least some of the steps in fig. 2 and 7 may include multiple sub-steps or multiple stages that are not necessarily performed at the same time, but may be performed at different times, and the order of performing the sub-steps or stages is not necessarily sequential, but may be performed in turn or alternately with other steps or at least some of the sub-steps or stages of other steps.

In one embodiment, as shown in fig. 9, there is provided a house structure generating apparatus including:

an obtaining module 100, configured to obtain a simulation wall of a design model;

a marking module 200, configured to mark a room on a simulation wall of the design model, to obtain a component model for distinguishing a space of the design model;

the generating module 300 is configured to obtain a setting parameter corresponding to the component model, and generate the component model according to the setting parameter.

In one embodiment, the component model comprises a column model; the generating module 300 is specifically configured to obtain, through a setting dialog box of the column model, a section type of the column model, a section size of the column model, and a material of the column model, which are input by a user, and generate the column model according to the section type of the column model, the section size of the column model, and the material of the column model.

In one embodiment, the component model comprises a beam model; the generating module 300 is specifically configured to obtain, through a setup dialog box of the beam model, a cross-sectional type of the beam model, a cross-sectional size of the beam model, a material of the beam model, and whether a secondary beam is generated, which are input by a user, and generate the beam model according to the cross-sectional type of the beam model, the cross-sectional size of the beam model, the material of the beam model, and whether the secondary beam is generated.

In one embodiment, the generating module 300 is further configured to output a prompt message on the parameter setting interface, where the prompt message is: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof.

In one embodiment, the component model comprises a floor model; the generation module 300 is specifically configured to obtain the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by the user through the setting dialog box of the floor model, and generate the floor model according to the floor type, the floor model, the floor thickness and the total plate thickness.

In one embodiment, the component model comprises a roofing model; the generation module 300 is specifically configured to obtain, through a setting dialog box of the roof model, a roof section type, a beam section, a purlin type, a purlin specification, a material, and a cornice length of the roof model input by a user, and generate the roof model according to the roof section type, the beam section, the purlin type, the purlin specification, the material, and the cornice length.

In one embodiment, as shown in fig. 10, there is provided a house structure generating apparatus including:

an obtaining module 400, configured to obtain a simulation wall of a design model;

a marking module 500, configured to mark a room on a simulation wall of the design model, to obtain a component model for distinguishing a space of the design model; the component model comprises a column model, a beam model, a floor slab model and a roof model;

a first generating module 600, configured to obtain, through a setting dialog box of the column model, a section type of the column model, a section size of the column model, and a material of the column model, which are input by a user, and generate the column model according to the section type of the column model, the section size of the column model, and the material of the column model;

the second generating module 700 is configured to obtain, through a setting dialog box of the beam model, a cross-sectional type of the beam model, a cross-sectional size of the beam model, a material of the beam model, and whether a secondary beam is generated, where the cross-sectional type of the beam model, the cross-sectional size of the beam model, and the material of the beam model are input by a user; generating the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated or not, and outputting prompt information on a parameter setting interface, wherein the prompt information is as follows: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof;

a third generating module 800, configured to obtain, through a setting dialog box of the floor model, a floor type, a floor thickness, and a total plate thickness of the floor model input by a user, and generate the floor model according to the floor type, the floor thickness, and the total plate thickness;

the fourth generation module 900 is configured to obtain, through a setting dialog box of the roof model, a roof section type, a beam section, a purlin type, a purlin specification, a material, and an eaves length of the roof model input by a user, and generate the roof model according to the roof section type, the beam section, the purlin type, the purlin specification, the material, and the eaves length.

For specific definition of the housing structure generation device, reference may be made to the above definition of the housing structure generation method, which is not described herein again. The respective modules in the house structure generation apparatus described above may be implemented in whole or in part by software, hardware, and a combination thereof. The modules can be embedded in a hardware form or independent from a processor in the computer device, and can also be stored in a memory in the computer device in a software form, so that the processor can call and execute operations corresponding to the modules.

In one embodiment, a computer device is provided, comprising a memory and a processor, the memory having a computer program stored therein, the processor implementing the following steps when executing the computer program:

acquiring a simulation wall of a design model;

room marking is carried out on the simulation wall of the design model, and a component model for distinguishing the space of the design model is obtained;

and acquiring the setting parameters corresponding to the component model, and generating the component model according to the setting parameters.

In one embodiment, the component model comprises a column model; the processor, when executing the computer program, further performs the steps of:

acquiring the section type of the column model, the section size of the column model and the material of the column model, which are input by a user, through a setting dialog box of the column model;

and generating the column model according to the section type of the column model, the section size of the column model and the material of the column model.

In one embodiment, the component model comprises a beam model; the processor, when executing the computer program, further performs the steps of:

acquiring the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated, which are input by a user, through a setting dialog box of the beam model;

and generating the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated.

In one embodiment, the processor, when executing the computer program, further performs the following steps of outputting a prompt message on the parameter setting interface, where the prompt message is: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof.

In one embodiment, the component model comprises a floor model; the processor, when executing the computer program, further performs the steps of:

acquiring the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by a user through a setting dialog box of the floor model;

and generating the floor slab model according to the floor slab type, the floor slab model, the floor slab thickness and the total plate thickness.

In one embodiment, the component model comprises a roofing model; the processor, when executing the computer program, further performs the steps of:

acquiring the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length of the roof model input by a user through a setting dialog box of the roof model;

and generating the roof model according to the type of the roof section, the beam section, the type of the purline, the specification of the purline, the material and the cornice length.

It should be clear that, in the embodiments of the present application, the process of executing the computer program by the processor is consistent with the process of executing the steps in the above method, and specific reference may be made to the description above.

In one embodiment, a computer device is provided, comprising a memory and a processor, the memory having a computer program stored therein, the processor implementing the following steps when executing the computer program:

acquiring a simulation wall of a design model;

room marking is carried out on the simulation wall of the design model, and a component model for distinguishing the space of the design model is obtained; the component model comprises a column model, a beam model, a floor slab model and a roof model;

acquiring the section type of the column model, the section size of the column model and the material of the column model, which are input by a user, through a setting dialog box of the column model;

generating the column model according to the section type of the column model, the section size of the column model and the material of the column model;

acquiring the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated, which are input by a user, through a setting dialog box of the beam model;

generating the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated or not;

outputting prompt information on a parameter setting interface, wherein the prompt information is as follows: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof;

acquiring the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by a user through a setting dialog box of the floor model;

generating the floor model according to the floor type, the floor model, the floor thickness and the total plate thickness;

acquiring the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length of the roof model input by a user through a setting dialog box of the roof model;

and generating the roof model according to the type of the roof section, the beam section, the type of the purline, the specification of the purline, the material and the cornice length.

It should be clear that, in the embodiments of the present application, the process of executing the computer program by the processor is consistent with the process of executing the steps in the above method, and specific reference may be made to the description above.

In one embodiment, a computer-readable storage medium is provided, having a computer program stored thereon, which when executed by a processor, performs the steps of:

acquiring a simulation wall of a design model;

room marking is carried out on the simulation wall of the design model, and a component model for distinguishing the space of the design model is obtained;

and acquiring the setting parameters corresponding to the component model, and generating the component model according to the setting parameters.

In one embodiment, the component model comprises a column model; the computer program when executed by the processor further realizes the steps of:

acquiring the section type of the column model, the section size of the column model and the material of the column model, which are input by a user, through a setting dialog box of the column model;

and generating the column model according to the section type of the column model, the section size of the column model and the material of the column model.

In one embodiment, the component model comprises a beam model; the computer program when executed by the processor further realizes the steps of:

acquiring the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated, which are input by a user, through a setting dialog box of the beam model;

and generating the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated.

In one embodiment, the computer program when executed by the processor further performs the following steps

Outputting prompt information on a parameter setting interface, wherein the prompt information is as follows: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof.

In one embodiment, the component model comprises a floor model; the computer program when executed by the processor further realizes the steps of:

acquiring the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by a user through a setting dialog box of the floor model;

and generating the floor slab model according to the floor slab type, the floor slab model, the floor slab thickness and the total plate thickness.

In one embodiment, the component model comprises a roofing model; the computer program when executed by the processor further realizes the steps of:

acquiring the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length of the roof model input by a user through a setting dialog box of the roof model;

and generating the roof model according to the type of the roof section, the beam section, the type of the purline, the specification of the purline, the material and the cornice length.

It should be clear that, in the embodiments of the present application, the process of executing the computer program by the processor is consistent with the process of executing the steps in the above method, and specific reference may be made to the description above.

In one embodiment, a computer-readable storage medium is provided, having a computer program stored thereon, which when executed by a processor, performs the steps of:

acquiring a simulation wall of a design model;

room marking is carried out on the simulation wall of the design model, and a component model for distinguishing the space of the design model is obtained; the component model comprises a column model, a beam model, a floor slab model and a roof model;

acquiring the section type of the column model, the section size of the column model and the material of the column model, which are input by a user, through a setting dialog box of the column model;

generating the column model according to the section type of the column model, the section size of the column model and the material of the column model;

acquiring the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated, which are input by a user, through a setting dialog box of the beam model;

generating the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated or not;

outputting prompt information on a parameter setting interface, wherein the prompt information is as follows: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof;

acquiring the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by a user through a setting dialog box of the floor model;

generating the floor model according to the floor type, the floor model, the floor thickness and the total plate thickness;

acquiring the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length of the roof model input by a user through a setting dialog box of the roof model;

and generating the roof model according to the type of the roof section, the beam section, the type of the purline, the specification of the purline, the material and the cornice length.

It should be clear that, in the embodiments of the present application, the process of executing the computer program by the processor is consistent with the process of executing the steps in the above method, and specific reference may be made to the description above.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium used in the embodiments provided herein may include non-volatile and/or volatile memory, among others. Non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), Double Data Rate SDRAM (DDRSDRAM), Enhanced SDRAM (ESDRAM), Synchronous Link DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM).

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (11)

1. A method of building structure generation, the method comprising:

acquiring a simulation wall of a design model;

room marking is carried out on the simulation wall of the design model, and a component model for distinguishing the space of the design model is obtained;

and acquiring the setting parameters corresponding to the component model, and generating the component model according to the setting parameters.

2. The method of claim 1, wherein the component model comprises a column model; the obtaining of the setting parameters corresponding to the component model and the generation of the component model according to the setting parameters includes:

acquiring the section type of the column model, the section size of the column model and the material of the column model, which are input by a user, through a setting dialog box of the column model;

and generating the column model according to the section type of the column model, the section size of the column model and the material of the column model.

3. The method of claim 1 or 2, wherein the component model comprises a beam model; the obtaining of the setting parameters corresponding to the component model and the generation of the component model according to the setting parameters includes:

acquiring the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated, which are input by a user, through a setting dialog box of the beam model;

and generating the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated.

4. The method of claim 3, further comprising:

outputting prompt information on a parameter setting interface, wherein the prompt information is as follows: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof.

5. The method of claim 3, wherein the component model comprises a floor model; the obtaining of the setting parameters corresponding to the component model and the generation of the component model according to the setting parameters includes:

acquiring the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by a user through a setting dialog box of the floor model;

and generating the floor slab model according to the floor slab type, the floor slab model, the floor slab thickness and the total plate thickness.

6. The method of claim 5, wherein the component model comprises a roofing model; the obtaining of the setting parameters corresponding to the component model and the generation of the component model according to the setting parameters includes:

acquiring the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length of the roof model input by a user through a setting dialog box of the roof model;

and generating the roof model according to the type of the roof section, the beam section, the type of the purline, the specification of the purline, the material and the cornice length.

7. A method of building structure generation, the method comprising:

acquiring a simulation wall of a design model;

room marking is carried out on the simulation wall of the design model, and a component model for distinguishing the space of the design model is obtained; the component model comprises a column model, a beam model, a floor slab model and a roof model;

acquiring the section type of the column model, the section size of the column model and the material of the column model, which are input by a user, through a setting dialog box of the column model;

generating the column model according to the section type of the column model, the section size of the column model and the material of the column model;

acquiring the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated, which are input by a user, through a setting dialog box of the beam model;

generating the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated or not;

outputting prompt information on a parameter setting interface, wherein the prompt information is as follows: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof;

acquiring the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by a user through a setting dialog box of the floor model;

generating the floor model according to the floor type, the floor model, the floor thickness and the total plate thickness;

acquiring the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length of the roof model input by a user through a setting dialog box of the roof model;

and generating the roof model according to the type of the roof section, the beam section, the type of the purline, the specification of the purline, the material and the cornice length.

8. A building structure generation apparatus, characterized in that the apparatus comprises:

the acquisition module is used for acquiring a simulation wall of the design model;

the marking module is used for marking rooms on the simulation wall of the design model to obtain a component model for distinguishing the space of the design model;

and the generating module is used for acquiring the setting parameters corresponding to the component model and generating the component model according to the setting parameters.

9. A building structure generation apparatus, characterized in that the apparatus comprises:

the acquisition module is used for acquiring a simulation wall of the design model;

the marking module is used for marking rooms on the simulation wall of the design model to obtain a component model for distinguishing the space of the design model; the component model comprises a column model, a beam model, a floor slab model and a roof model;

the first generation module is used for acquiring the section type of the column model, the section size of the column model and the material of the column model input by a user through a setting dialog box of the column model, and generating the column model according to the section type of the column model, the section size of the column model and the material of the column model;

the second generation module is used for acquiring the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated, which are input by a user, through a setting dialog box of the beam model; generating the beam model according to the section type of the beam model, the section size of the beam model, the material of the beam model and whether a secondary beam is generated or not, and outputting prompt information on a parameter setting interface, wherein the prompt information is as follows: the top elevation does not generate a beam in the design mode, and the top elevation ground beam is generated by the roof;

the third generation module is used for acquiring the floor type, the floor model, the floor thickness and the total plate thickness of the floor model input by a user through a setting dialog box of the floor model, and generating the floor model according to the floor type, the floor model, the floor thickness and the total plate thickness;

and the fourth generation module is used for acquiring the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length of the roof model input by a user through a setting dialog box of the roof model, and generating the roof model according to the roof section type, the beam section, the purlin type, the purlin specification, the material and the cornice length.

10. A computer device comprising a memory and a processor, the memory storing a computer program, wherein the processor implements the steps of the method of any one of claims 1 to 8 when executing the computer program.

11. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method of any one of claims 1 to 8.

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