CN114186326A - Method, device, equipment and storage medium for generating suspended ceiling structure model - Google Patents
Method, device, equipment and storage medium for generating suspended ceiling structure model Download PDFInfo
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Abstract
The embodiment of the invention discloses a method, a device, equipment and a storage medium for generating a suspended ceiling structure model. A method for generating a suspended ceiling structure model comprises the following steps: receiving target parameters of the suspended ceiling structure input by a user; calculating target component data of the suspended ceiling structure model according to the target parameters by adopting a suspended ceiling structure model generation algorithm; and generating a target suspended ceiling structure model and a target component data list according to the target component data. The problems that an existing design platform is poor in operability and few in applicable scenes, the workload is large and the design efficiency is low due to the fact that the material calculation amount of accessories of a model needs to be calculated independently are solved, statistics and output of a component data list of a suspended ceiling structure model are achieved by utilizing algorithm advantages, the design efficiency of the suspended ceiling structure model is improved, and the labor cost is also reduced.
Description
Technical Field
The embodiment of the invention relates to the technical field of building design, in particular to a method, a device, equipment and a storage medium for generating a suspended ceiling structure model.
Background
In general, BIM modeling design software-a modeling master based on a Revit platform is adopted in interior decoration design, and the system has the functions of quickly arranging a suspended ceiling, supporting a drop-level suspended ceiling, laying keels and the like. The function supports the lineation to draw a suspended ceiling plane with any shape, the existing suspended ceiling is lineated and cut, the angle is set to draw the drop-level suspended ceiling and support the arrangement and continuous and straight laying on the suspended ceiling plane, and the suspended ceiling is in various forms such as a bar grid and a grid in a shape like a Chinese character jing. And supporting and arranging various U-shaped, C-shaped, Y-shaped and T-shaped keels on the drawn ceiling plane, and setting detailed parameters including keel accessories. Finally, the generated ceiling model is displayed on a Revit platform for further operation. The operation method of the software can be roughly divided into four steps of ceiling plane setting, ceiling falling level setting, ceiling arrangement and ceiling keel arrangement. The user can input various parameters such as the edge distance of the bearing keel, the space between the cladding keels, the edge distance of the cross-brace keel, the length of the edge keel, the length of the cladding keel, the length of the bearing keel, the space between the hanging rods and the like so as to generate a keel model meeting the project conditions.
However, the Revit platform has a very clear initial use requirement for the initial use environment, and has low adaptability to other software. The software only provides a specific keel, which does not meet the requirements of designers for components with different sizes in the actual construction process. The software is weak in applicability and operability outside the preset component, application scenes are few, and material calculation amount of each accessory corresponding to the generated model needs to be additionally counted and output, so that workload is increased, and design efficiency is reduced.
Disclosure of Invention
The invention provides a method, a device, equipment and a storage medium for generating a suspended ceiling structure model, which are used for counting and outputting a component data list of the suspended ceiling structure model by using algorithm advantages, improving the design efficiency of the suspended ceiling structure model and reducing the labor cost.
In a first aspect, an embodiment of the present invention provides a method for generating a suspended ceiling structure model, including:
receiving target parameters of the suspended ceiling structure input by a user;
calculating target component data of the suspended ceiling structure model according to the target parameters by adopting a suspended ceiling structure model generation algorithm;
and generating a target suspended ceiling structure model and a target component data list according to the target component data.
Optionally, after generating the target suspended ceiling structural model and the target component data list according to the target component data, the method further includes:
receiving at least one target parameter updated by a user;
and updating the target suspended ceiling structure model and the target component data list according to the suspended ceiling structure model generation algorithm.
Optionally, the target parameters of the ceiling structure include: geometric data and numerical data;
the geometric data includes: the suspended ceiling structure comprises a suspended ceiling structure edge line, a beam line and a preset fixed model; the preset fixing model comprises a connecting piece fixing model and a bolt fixing model;
the numerical data includes: the size of the cover panel, the structural parameters of the beam, the installation density of the suspender unit, the diameter of the suspender and the distance between bolts.
Optionally, the obtaining of target component data of the suspended ceiling structure model by using an automatic generation algorithm of the suspended ceiling structure model and calculating according to the target parameters includes:
calculating and generating a suspender unit according to the size of the suspender member and a preset fixed model;
determining the distribution data of the suspender units of each beam line according to the installation density of the suspender units; determining a suspended ceiling array according to the distribution data of the suspender units of each beam line and the distribution of the beam lines;
determining a datum line and a section size of a keel according to the ceiling array, calling a preset keel model, and generating a ceiling keel unit; determining keel arrangement data according to the datum line and the suspended ceiling keel unit;
and generating the cover panel according to the ceiling structure edge line and the size of the cover panel.
Optionally, the reference line and the section size of the keel are determined according to the ceiling array, and a preset keel model is called to generate a ceiling keel unit; determining keel arrangement data according to the datum line and the ceiling keel unit, comprising:
determining hanger rod units perpendicular to the beam line in the suspended ceiling array as a same group of hanger rod units;
generating a datum line of the suspended ceiling keel unit according to the same group of hanger rod units;
determining the section size of the ceiling keel unit according to the spacing of the ceiling array;
calling a preset keel model according to the datum line and the section size to generate a suspended ceiling keel unit;
and arranging the suspended ceiling keel units according to the reference lines, and determining keel arrangement data.
Optionally, the generating a target suspended ceiling structural model and a target component data list according to the target component data includes:
calculating the number of the suspender units, the number of the connecting pieces and the number of the bolts according to the suspended ceiling array;
calculating the number of the suspended ceiling keel units according to the keel arrangement data;
acquiring the number of the cover panels;
and generating a first target component data list according to the number and the size data of various target components and the types of the target components.
Optionally, the generating a target suspended ceiling structural model and a target component data list according to the target component data further includes:
acquiring material information of the target component, and calculating the total consumption;
and integrating the target component with the first target component data list according to the type of the target component to obtain a second target component data list.
In a second aspect, an embodiment of the present invention further provides a device for generating a suspended ceiling structural model, including:
the target parameter receiving module is used for receiving target parameters of the suspended ceiling structure input by a user;
the target component data determining module is used for calculating target component data of the suspended ceiling structure model according to the target parameters by adopting a suspended ceiling structure model generating algorithm;
and the target model and component data list generation module is used for generating a target suspended ceiling structure model and a target component data list according to the target component data.
In a third aspect, an embodiment of the present invention further provides a device for generating a suspended ceiling structural model, where the device for generating a suspended ceiling structural model includes:
one or more processors;
a storage device for storing one or more programs,
when executed by the one or more processors, cause the one or more processors to implement a method of generating a model of a suspended ceiling structure as set forth in any one of the first aspects.
In a fourth aspect, the present invention further provides a computer-readable storage medium, on which a computer program is stored, where the computer program, when executed by a processor, implements the method for generating the suspended ceiling structure model according to any one of the first aspect.
The invention provides a method for generating a suspended ceiling structure model, which comprises the following steps: receiving target parameters of the suspended ceiling structure input by a user; calculating target component data of the suspended ceiling structure model according to the target parameters by adopting a suspended ceiling structure model generation algorithm; and generating a target suspended ceiling structure model and a target component data list according to the target component data. The problems that an existing design platform is poor in operability and few in applicable scenes, the workload is large and the design efficiency is low due to the fact that the material calculation amount of accessories of a model needs to be calculated independently are solved, statistics and output of a component data list of a suspended ceiling structure model are achieved by utilizing algorithm advantages, the design efficiency of the suspended ceiling structure model is improved, and the labor cost is also reduced.
Drawings
Fig. 1A is a schematic flow chart of a method for generating a suspended ceiling structural model according to a first embodiment of the present invention;
fig. 1B is a schematic flow chart of another method for generating a suspended ceiling structural model according to a first embodiment of the present invention;
fig. 2 is a schematic structural diagram of a boom unit generated in a method for generating a suspended ceiling structural model according to an embodiment of the present invention;
fig. 3A is a schematic structural diagram of a ceiling keel framework model generated in a method for generating a ceiling structural model according to an embodiment of the present invention;
fig. 3B is a schematic structural diagram of another ceiling keel framework model generated in the method for generating a ceiling structural model according to the first embodiment of the present invention;
fig. 4 is a schematic structural diagram of a device for generating a suspended ceiling structural model according to a second embodiment of the present invention;
fig. 5 is a schematic structural diagram of a device for generating a suspended ceiling structural model according to a third embodiment of the present invention.
Detailed Description
The present invention will be described in further detail with reference to the accompanying drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not limiting of the invention. It should be further noted that, for the convenience of description, only some of the structures related to the present invention are shown in the drawings, not all of the structures.
Example one
Fig. 1A is a schematic flow diagram of a method for generating a suspended ceiling structural model according to a first embodiment of the present invention, and fig. 1B is a schematic flow diagram of a method for generating another suspended ceiling structural model according to a first embodiment of the present invention.
As shown in fig. 1A, a method for generating a suspended ceiling structure model specifically includes the following steps:
and 110, receiving target parameters of the suspended ceiling structure input by a user.
The suspended ceiling is a decoration of the top decoration of the residential environment of a house, and is one of important parts of indoor decoration. The suspended ceiling has the main functions of preventing water and air infiltration and oil smoke scattering, hiding light pipelines, adjusting the ceiling to be horizontal when the roof is not horizontal, and the like. Suspended ceiling structures are widely used as a decorative structure with various structural forms in the indoor decoration process.
Wherein, the target parameter of furred ceiling structure includes: geometric data and numerical data. The geometric data includes: the suspended ceiling structure comprises a suspended ceiling structure edge line, a beam line and a preset fixed model; the preset fixing model comprises a connecting piece fixing model and a bolt fixing model. The numerical data includes: the size of the cover panel, the structural parameters of the beam, the installation density of the suspender unit, the diameter of the suspender and the distance between bolts.
Before generating the model of the suspended ceiling structure, the area and the size of the suspended ceiling in the room, namely the edge line of the suspended ceiling structure, need to be determined. The frame line of furred ceiling structure bottom edge is furred ceiling structure edge line, and the furred ceiling structure bottom edge is the mat facing board bottom edge, and furred ceiling structure edge line can be one or more closed broken line, and the shape of furred ceiling structure edge line is the rectangle or for the rectangle that has two angle indents.
The beam line is a lower line of a beam of the fixable ceiling at the top of a room, the beam line is obtained by calculation of a box structure generation algorithm, the beam line is a plurality of equidistant parallel straight line segments, the data of the beam line comprises the distribution data and the length of the plurality of beam lines, and the suspension range and the mounting track of the suspender unit connected with the beam line can be determined through the beam line.
Fixed model is including connecting fixed model and the fixed model of bolt, and the fixed model of connection that this embodiment adopted is the angle steel component model, and the fixed model of connecting piece includes the shape and the size of angle steel component, and the angle steel component is the rectangular steel of both sides mutually perpendicular formation angle shape, and the length that the size of the angle steel component of this embodiment is both sides is 50 mm. The bolt fixing model comprises the shape and the size of a bolt and the distance between two bolts, the bolt in the embodiment is a hexagon bolt, the distance between opposite vertexes of the nut is 13mm, and the size of two opposite parallel surfaces in six side surfaces of the nut is 11 mm. A plurality of bolts are arranged on one suspension rod, and the bolt distance between the center points of the two bolts is determined by the form of a component and is 3mm in default.
The cover surface plate covers the part of sheltering from original ceiling for in the furred ceiling, shelves or fixes on fossil fragments skeleton, and the material variety is many, and mineral wool board, plank, gypsum board, plastic slab, light alloy board are all common cover surface plate. The size of the cover panel comprises the thickness and the shape of the cover panel, the shape of the cover panel needs to be confirmed according to the partition size of the wall panel because the partition of the cover panel needs to be aligned with the partition of the wall surface, the data type of the thickness of the cover panel is a real number which is greater than 0 and is used for representing the thickness of the cover panel, and the default is 100mm in general.
The beam structure parameters comprise the section width and the section height of the beam structure, wherein the section width is the transverse width of the section of the beam and is used for representing the size of the beam in the horizontal direction, and the default is 100mm in general; the cross-sectional height is the lateral height of the cross-section of the beam, and is used to indicate the dimension of the beam in the vertical direction, typically by default 100 mm.
A plurality of jib units of regular installation on same root roof beam, the distance between two adjacent jib axis is jib density, and in order to guarantee the security of furred ceiling structure, jib installation density need be in setting for the within range, and acquiescence jib density is 100 mm. The boom diameter defaults to 4 mm.
And 120, calculating target component data of the suspended ceiling structure model according to the target parameters by adopting a suspended ceiling structure model generation algorithm.
The number, length and size of the hanger bars are often determined by the component materials provided by the manufacturer, the dimensions of the room, and the room usage function. When the suspended ceiling is installed, the suspension rod is usually fixed on a beam structure of a room through the connecting member according to a certain distance to form a main tension member, the lower part of the suspension rod is connected with the suspended ceiling keel, and finally, the fixing plate is arranged on the lower part of the suspended ceiling keel.
Wherein, step 120 specifically includes:
and step 121, calculating and generating a suspender unit according to the size of the suspender component and a preset fixed model.
As shown in fig. 2, the members for forming the boom unit 1 include a boom 11, a connecting member 12, and a bolt 13, the boom 11 is connected to the beam through the connecting member 12, the boom 11 and the connecting member 12 are fixed by the bolt 13, and the boom 11 and the cover panel at the lower end of the boom 11 are fixed by the bolt 13; the component dimensions include: boom size, link size, and bolt size. The hanger rod size includes hanger rod diameter and hanger rod length, and the beam line is as the upper edge of furred ceiling structure, and furred ceiling structure edge line is the lower limb of furred ceiling structure, and hanger rod length is confirmed according to the perpendicular distance between beam line and the furred ceiling structure edge line.
And automatically calculating and generating a suspender unit for subsequent arrangement according to the size of the suspender component and a preset fixed model.
Step 122, determining the distribution data of the suspender units of each beam line according to the installation density of the suspender units; and determining the suspended ceiling array according to the distribution data of the suspender units of each beam line and the distribution of the beam lines.
And according to the installation density of the suspender units, symmetrically arranging the suspender units from the middle to two sides on the beam corresponding to each beam line, and determining the suspender unit distribution data of each beam line.
Calculating the number of the suspender units mounted on the beam corresponding to each beam line according to the mounting density of the suspender units and the length of each beam line, symmetrically arranging the suspender units on the beam from the middle to two sides, completing the mounting of the suspender units on the beam corresponding to all the beam lines, and determining the distribution data of the suspender units of each beam line, wherein the distribution data specifically comprises the number and position information of the suspender units of each beam line.
Because the roof beam line is the parallel straightway of a plurality of equidistance, after the installation jib unit was accomplished on every roof beam line corresponds the roof beam, the jib unit was the array and arranges.
Step 123, determining a datum line and a section size of a keel according to the ceiling array, calling a preset keel model, and generating a ceiling keel unit; and determining keel arrangement data according to the datum line and the ceiling keel unit.
Wherein step 123 comprises:
and S1, determining the suspender units perpendicular to the beam line in the suspended ceiling array as the same group of suspender units.
And S2, generating a reference line of the ceiling keel unit according to the same group of hanger rod units.
S4, determining the section size of the ceiling keel unit according to the spacing of the ceiling array;
and S3, calling a preset keel model according to the datum line and the section size to generate a suspended ceiling keel unit.
And S4, arranging the ceiling keel units according to the reference lines, and determining keel arrangement data.
The ceiling keel is connected with the hanger rod, provides a mounting node for the surface cover panel and supports the components which are opened and closed in the ceiling structure.
Because indoor ceiling is the horizontal plane, the jib length of jib unit is unanimous, consequently, the bottom highly uniform of jib unit, confirms the line that a plurality of jib units in the furred ceiling array establish ties in proper order and the perpendicular jib unit of beam line as the jib unit of the same group, and the jib unit of the same group corresponds same furred ceiling keel unit, according to the straightway that the bottom of the jib unit of the same group generated, as the datum line that generates furred ceiling keel.
The keel model comprises keel models such as U, C, V and T shapes, the keel model adopted in the embodiment is of a single section size, and is packaged into a callable class, and the callable class is called by inputting a datum line of the keel and a coordinate system with one end of the datum line perpendicular to the datum line. Illustratively, the embodiment adopts a U-shaped keel model, and the default parameters are that the side length of the section is 44mm, and the thickness is 3 mm. Specifically, the cross sectional dimension of the ceiling keel unit can be determined according to the distance between the suspender units in the ceiling array, and a preset keel model is called according to the determined datum line and the cross sectional dimension to generate the ceiling keel unit corresponding to the suspender unit.
The keel frame is a frame used for laying and installing ceiling boards, is usually made of alloy materials, and is also made of wood in part of ceilings. Generating a plurality of reference lines according to the ceiling array, wherein each reference line corresponds to one ceiling keel unit, and determining the arrangement positions of the ceiling keel units according to the arrangement positions of all the reference lines; the length of furred ceiling keel unit is confirmed jointly by datum line and furred ceiling structure edge line, as shown in fig. 3A, it is perpendicular with roof beam 2 with the same group's jib unit of constituteing by a plurality of jib unit 1, datum line according to the same group's jib unit confirms generates furred ceiling keel unit 3, furred ceiling keel unit 3 is inside furred ceiling structure edge line 4, when furred ceiling structure edge line 4's shape is the rectangle, the furred ceiling keel unit 3's that generates length is unanimous, as shown in fig. 3B, when furred ceiling structure edge line 4's shape is the rectangle that has two angles indent, furred ceiling keel unit 3's length is the distance between two nodical points of the straight line at the datum line place that corresponds and furred ceiling structure edge line 4. And determining keel arrangement data according to the arrangement position and the length of the ceiling keel unit, namely forming a ceiling keel framework model.
And 124, generating the cover panel according to the edge line of the suspended ceiling structure and the size of the cover panel.
Determining the installation range, position data and size data of the cover panel according to the edge line of the suspended ceiling structure and the suspended ceiling keel framework model, namely determining the size of each cover panel obtained by segmentation according to the input segmentation size of the wall panel; illustratively, each of the panels is rectangular, and is generated based on the size data, i.e., length data and width data, of each panel, and the user-entered panel thickness or the called default panel thickness. The technical scheme of this embodiment regards the input cover panel thickness and the furred ceiling structure edge line as the output to make things convenient for the subsequent cover panel of platform to generate the calling of algorithm.
And step 130, generating a target suspended ceiling structure model and a target component data list according to the target component data.
And assembling target component data according to the position data and a preset connection relation to generate a three-dimensional suspended ceiling structure model, displaying the suspended ceiling structure model on a display screen, and checking the suspended ceiling structure model through dragging, clicking and other operations by a user.
Wherein, while generating the suspended ceiling structural model, step 130 further comprises: generating a target component data list according to the target component data, which specifically comprises the following steps:
and step 131, calculating the number of the suspender units, the number of the connecting pieces and the number of the bolts according to the suspended ceiling array.
And 132, calculating the number of the suspended ceiling keel units according to the keel arrangement data.
And step 133, acquiring the number of the cover panels.
And step 134, generating a first target component data list according to the number and the size data of various target components and the types of the target components.
The number of the suspender units, namely the number of the suspenders, is obtained according to the suspended ceiling array, the number of the connecting pieces and the number of the bolts which are correspondingly connected with each suspender are the same, and the number of the connecting pieces and the number of the bolts are determined according to the number of the suspenders. And determining the number of the ceiling keel units and the length of each ceiling keel unit according to keel arrangement data. The number of panels and the panel size are obtained. According to the number of various components for generating the suspended ceiling structure model, namely the number of suspenders, the number of connecting pieces, the number of bolts, the number of suspended ceiling keel units and the number of cover panels, a component number list is generated, size data of various components are obtained, a first target component data list is generated according to the types of the components and output, the first target component data list is conveniently collected into a material list and displayed in a table form, and guidance is provided for site construction.
And step 135, acquiring material information of the target component, and calculating the total consumption.
And step 136, integrating the data list of the first target component according to the type of the target component to obtain a data list of a second target component.
The method comprises the steps of obtaining material information of various components for generating the suspended ceiling structure model, calculating the total material consumption, conducting overall planning on design material consumption of the suspended ceiling structure model, integrating the material and the total material consumption information with a first target component data list according to the type of a target component, generating a component data list containing the quantity, the size, the material and the total material consumption of the component, and facilitating control of the total material consumption and the cost of construction of the suspended ceiling structure by a user.
The technical scheme that this embodiment provided can deploy in the high in the clouds, supplies a plurality of users to use, and the user can call furred ceiling structure model generating algorithm at the target parameter of high in the clouds server input furred ceiling structure, calculates and generates target furred ceiling structure model to output target component data list simultaneously, including quantity, size and the total quantity of component and material, conveniently gather in the bill of materials, direct guide actual construction.
The invention provides a method for generating a suspended ceiling structure model, which comprises the following steps: receiving target parameters of the suspended ceiling structure input by a user; calculating target component data of the suspended ceiling structure model according to the target parameters by adopting a suspended ceiling structure model generation algorithm; and generating a target suspended ceiling structure model and a target component data list according to the target component data. The problems that an existing design platform is poor in operability and few in applicable scenes, the workload is large and the design efficiency is low due to the fact that the material calculation amount of accessories of a model needs to be calculated independently are solved, statistics and output of a component data list of a suspended ceiling structure model are achieved by utilizing algorithm advantages, the design efficiency of the suspended ceiling structure model is improved, and the labor cost is also reduced.
On the basis of the technical solution of the foregoing embodiment, as shown in fig. 1B, further after generating a target ceiling structure model and a target component data list according to the target component data, the method further includes:
And 150, updating the target ceiling structure model and the target component data list according to the ceiling structure model generation algorithm.
The user can update the target parameters through the input end according to actual needs, for example, any parameter in geometric data and numerical data is modified, customized adjustment is carried out on the production results, and the suspended ceiling structure model and the target component data list are updated in real time so as to adapt to various scene conditions, so that the practicability is improved, and the labor cost is also reduced.
Example two
Fig. 4 is a schematic structural diagram of a device for generating a suspended ceiling structural model according to a second embodiment of the present invention.
As shown in fig. 4, an apparatus for generating a model of a suspended ceiling structure includes:
and a target parameter receiving module 410, configured to receive a user input of a target parameter of the suspended ceiling structure.
And the target member data determining module 420 is used for calculating target member data of the suspended ceiling structure model according to the target parameters by adopting a suspended ceiling structure model generating algorithm.
And the target model and component data list generation module 430 is configured to generate a target suspended ceiling structural model and a target component data list according to the target component data.
The technical scheme provided by the embodiment of the invention comprises the following steps: receiving target parameters of the suspended ceiling structure input by a user; calculating target component data of the suspended ceiling structure model according to the target parameters by adopting a suspended ceiling structure model generation algorithm; and generating a target suspended ceiling structure model and a target component data list according to the target component data. The problems that an existing design platform is poor in operability and few in applicable scenes, the workload is large and the design efficiency is low due to the fact that the material calculation amount of accessories of a model needs to be calculated independently are solved, statistics and output of a component data list of a suspended ceiling structure model are achieved by utilizing algorithm advantages, the design efficiency of the suspended ceiling structure model is improved, and the labor cost is also reduced.
On the basis of the foregoing technical solution, optionally, the target parameter receiving module 410 includes:
the geometric data receiving unit is used for receiving the edge line, the beam line and the preset fixed model of the suspended ceiling structure; the preset fixing model comprises a connecting piece fixing model and a bolt fixing model.
And the numerical data receiving unit is used for receiving the size of the cover panel, the beam structure parameters, the mounting density of the suspender unit, the diameter of the suspender and the bolt spacing.
On the basis of the above technical solution, optionally, the target member data determining module 420 includes:
and the suspender unit generating unit is used for calculating and generating the suspender unit according to the size of the suspender member and the preset fixed model.
And the suspender unit distribution determining unit is used for determining suspender unit distribution data of each beam line according to the installation density of the suspender units.
Wherein the boom unit distribution determining unit includes:
and the distribution data determining subunit is used for symmetrically arranging the suspender units from the middle to two sides on the beam corresponding to each beam line according to the installation density of the suspender units and determining the distribution data of the suspender units of each beam line.
And the suspended ceiling array determining unit is used for determining the suspended ceiling array according to the distribution data of the suspender units of each beam line and the distribution of the beam lines.
The keel arrangement data determining unit is used for determining a datum line and a section size of a keel according to the suspended ceiling array, calling a preset keel model and generating a suspended ceiling keel unit; and determining keel arrangement data according to the datum line and the ceiling keel unit.
Wherein, fossil fragments range data determine unit includes:
and the same group of suspender unit determining subunit is used for determining the suspender units vertical to the beam line in the suspended ceiling array as the same group of suspender units.
And the datum line determining subunit is used for generating the datum line of the suspended ceiling keel unit according to the same group of hanger rod units.
And the keel section size determining subunit is used for determining the section size of the ceiling keel unit according to the interval of the ceiling array.
And the suspended ceiling keel unit generation subunit is used for calling a preset keel model according to the datum line and the section size to generate a suspended ceiling keel unit.
And the keel arrangement data determining subunit is used for arranging the suspended ceiling keel units according to the datum line and determining keel arrangement data.
And the cover panel generating unit is used for generating the cover panel according to the edge line of the suspended ceiling structure and the size of the cover panel.
On the basis of the above technical solution, optionally, the target model and component data list generating module 430 includes:
and the suspender unit component data determining unit is used for calculating the number of the suspender units, the number of the connecting pieces and the number of the bolts according to the suspended ceiling array.
And the ceiling keel unit quantity determining unit is used for calculating the quantity of the ceiling keel units according to the keel arrangement data.
And the number obtaining unit is used for obtaining the number of the cover panels.
And a first target member data list generation unit for generating a first target member data list by the kind of the target member based on the number and size data of the various target members.
On the basis of the above technical solution, optionally, the target model and component data list generating module 430 further includes:
and the material usage determining unit is used for acquiring the material information of the target component and calculating the total usage.
And the second target component data list generating unit is used for integrating the first target component data list according to the type of the target component to obtain a second target component data list.
On the basis of the above technical solution, optionally, a device for generating a suspended ceiling structural model further includes:
and the parameter updating module is used for receiving at least one target parameter updated by the user.
And the target model and component data list updating module is used for updating the target suspended ceiling structure model and the target component data list according to the suspended ceiling structure model generation algorithm.
The user can update the target parameters through the input end according to actual needs, and the suspended ceiling structure model and the target component data list are updated in real time so as to adapt to various scene conditions, improve the practicability and reduce the labor cost.
The device for generating the suspended ceiling structure model provided by the embodiment of the invention can execute the method for generating the suspended ceiling structure model provided by any embodiment of the invention, and has corresponding functional modules and beneficial effects of the execution method.
It should be noted that, in the embodiment of the apparatus for generating a suspended ceiling structural model, the included units and modules are only divided according to functional logic, but are not limited to the above division, as long as the corresponding functions can be realized; in addition, specific names of the functional units are only for convenience of distinguishing from each other, and are not used for limiting the protection scope of the present invention.
EXAMPLE III
Fig. 5 is a schematic structural diagram of a device for generating a model of a suspended ceiling structure according to a third embodiment of the present invention, and as shown in fig. 5, the device for generating a model of a suspended ceiling structure includes a processor 50, a memory 51, an input device 52, and an output device 53; the number of the processors 50 in the generation device of the suspended ceiling structure model can be one or more, and one processor 50 is taken as an example in fig. 5; the processor 50, the memory 51, the input device 52 and the output device 53 in the apparatus for generating the model of the suspended ceiling structure may be connected by a bus or other means, and fig. 5 illustrates the connection by the bus as an example.
The memory 51 is used as a computer-readable storage medium for storing software programs, computer-executable programs, and modules, such as program instructions/modules corresponding to the generation method of the suspended ceiling structure model in the embodiment of the present invention (for example, the target parameter receiving module 410, the target component data determining module 420, and the target model and component data list generating module 430 in the generation device of the suspended ceiling structure model). The processor 50 executes various functional applications and data processing of the apparatus for generating the ceiling structural model by executing software programs, instructions and modules stored in the memory 51, that is, implements the method for generating the ceiling structural model described above.
The memory 51 may mainly include a storage program area and a storage data area, wherein the storage program area may store an operating system, an application program required for at least one function; the storage data area may store data created according to the use of the terminal, and the like. Further, the memory 51 may include high speed random access memory, and may also include non-volatile memory, such as at least one magnetic disk storage device, flash memory device, or other non-volatile solid state storage device. In some examples, the memory 51 may further include memory remotely located from the processor 50, and these remote memories may be connected to the generation device of the ceiling structural model through a network. Examples of such networks include, but are not limited to, the internet, intranets, local area networks, mobile communication networks, and combinations thereof.
The input device 52 is operable to receive input numeric or character information and to generate key signal inputs relating to user settings and function controls of the suspended ceiling structural model generating apparatus. The output device 53 may include a display device such as a display screen.
Example four
A fourth embodiment of the present invention further provides a storage medium containing computer-executable instructions, which when executed by a computer processor, perform a method for generating a model of a suspended ceiling structure, the method including:
receiving target parameters of the suspended ceiling structure input by a user;
calculating target component data of the suspended ceiling structure model according to the target parameters by adopting a suspended ceiling structure model generation algorithm;
and generating a target suspended ceiling structure model and a target component data list according to the target component data.
Of course, the storage medium provided by the embodiment of the present invention contains computer-executable instructions, and the computer-executable instructions are not limited to the operations of the method described above, and may also perform related operations in the method for generating a suspended ceiling structural model provided by any embodiment of the present invention.
From the above description of the embodiments, it is obvious for those skilled in the art that the present invention can be implemented by software and necessary general hardware, and certainly, can also be implemented by hardware, but the former is a better embodiment in many cases. Based on such understanding, the technical solutions of the present invention may be embodied in the form of a software product, which can be stored in a computer-readable storage medium, such as a floppy disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a FLASH Memory (FLASH), a hard disk or an optical disk of a computer, and includes several instructions for enabling a computer device (which may be a personal computer, a server, or a network device) to execute the methods according to the embodiments of the present invention.
It should be understood that various forms of the flows shown above may be used, with steps reordered, added, or deleted. For example, the steps described in the present invention may be executed in parallel, sequentially, or in different orders, and are not limited herein as long as the desired results of the technical solution of the present invention can be achieved.
The above-described embodiments should not be construed as limiting the scope of the invention. It should be understood by those skilled in the art that various modifications, combinations, sub-combinations and substitutions may be made in accordance with design requirements and other factors. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.
Claims (10)
1. A method for generating a suspended ceiling structural model is characterized by comprising the following steps:
receiving target parameters of the suspended ceiling structure input by a user;
calculating target component data of the suspended ceiling structure model according to the target parameters by adopting a suspended ceiling structure model generation algorithm;
and generating a target suspended ceiling structure model and a target component data list according to the target component data.
2. The method for generating a ceiling structural model according to claim 1, wherein after generating a target ceiling structural model and a target component data list from the target component data, the method further comprises:
receiving at least one target parameter updated by a user;
and updating the target suspended ceiling structure model and the target component data list according to the suspended ceiling structure model generation algorithm.
3. The method of generating a model of a suspended ceiling structure of claim 1, wherein the target parameters of the suspended ceiling structure comprise: geometric data and numerical data;
the geometric data includes: the suspended ceiling structure comprises a suspended ceiling structure edge line, a beam line and a preset fixed model; the preset fixing model comprises a connecting piece fixing model and a bolt fixing model;
the numerical data includes: the size of the cover panel, the structural parameters of the beam, the installation density of the suspender unit, the diameter of the suspender and the distance between bolts.
4. The method for generating the suspended ceiling structural model according to claim 3, wherein the calculating target component data of the suspended ceiling structural model according to the target parameters by using the automatic generation algorithm of the suspended ceiling structural model comprises:
calculating and generating a suspender unit according to the size of the suspender member and a preset fixed model;
determining the distribution data of the suspender units of each beam line according to the installation density of the suspender units; determining a suspended ceiling array according to the distribution data of the suspender units of each beam line and the distribution of the beam lines;
determining a datum line and a section size of a keel according to the ceiling array, calling a preset keel model, and generating a ceiling keel unit; determining keel arrangement data according to the datum line and the suspended ceiling keel unit;
and generating the cover panel according to the ceiling structure edge line and the size of the cover panel.
5. The method for generating the suspended ceiling structure model according to claim 4, wherein the reference line and the section size of the keel are determined according to the suspended ceiling array, and a preset keel model is called to generate a suspended ceiling keel unit; determining keel arrangement data according to the datum line and the ceiling keel unit, comprising:
determining hanger rod units perpendicular to the beam line in the suspended ceiling array as a same group of hanger rod units;
generating a datum line of the suspended ceiling keel unit according to the same group of hanger rod units;
determining the section size of the ceiling keel unit according to the distance of the ceiling array;
calling a preset keel model according to the datum line and the section size to generate a suspended ceiling keel unit;
and arranging the suspended ceiling keel units according to the reference lines, and determining keel arrangement data.
6. The method for generating a ceiling structural model according to claim 4, wherein generating a target ceiling structural model and a target component data list according to the target component data comprises:
calculating the number of the suspender units, the number of the connecting pieces and the number of the bolts according to the suspended ceiling array;
calculating the number of the suspended ceiling keel units according to the keel arrangement data;
acquiring the number of the cover panels;
and generating a first target component data list according to the number and the size data of various target components and the types of the target components.
7. The method for generating a ceiling structural model according to claim 6, wherein generating a target ceiling structural model and a target component data list from the target component data further comprises:
acquiring material information of the target component, and calculating the total consumption;
and integrating the target component with the first target component data list according to the type of the target component to obtain a second target component data list.
8. A generation device of a suspended ceiling structure model is characterized by comprising:
the target parameter receiving module is used for receiving target parameters of the suspended ceiling structure input by a user;
the target component data determining module is used for calculating target component data of the suspended ceiling structure model according to the target parameters by adopting a suspended ceiling structure model generating algorithm;
and the target model and component data list generation module is used for generating a target suspended ceiling structure model and a target component data list according to the target component data.
9. A generation device of a suspended ceiling structural model is characterized by comprising:
one or more processors;
a storage device for storing one or more programs,
the one or more programs, when executed by the one or more processors, cause the one or more processors to implement a method of generating a model of a suspended ceiling structure as recited in any of claims 1-7.
10. A computer-readable storage medium, on which a computer program is stored, which program, when being executed by a processor, is adapted to carry out a method of generating a model of a suspended ceiling structure as set forth in any one of claims 1 to 7.
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