CN112883452A - Method, device and equipment for generating lighting design protection tube and storage medium - Google Patents

Abstract

The application relates to a method for generating a lighting design protection tube, which comprises the following steps: acquiring a building model and lighting equipment which needs to be arranged in the building model at present, and correspondingly installing the lighting equipment into the building model according to the installation mode of the lighting equipment; conducting wire connection on the lighting devices according to the connection relation among the lighting devices; configuring the laying mode of the protection pipe corresponding to different buildings in the building model based on the installation position of each lighting device in the building model; generating a laying path of a protection pipe according to a connecting wire between the lighting devices and a building located at the installation position of the lighting devices; and calculating the installation position information of the protection pipe according to the building corresponding to the laying path and the laying mode, and drawing the protection pipe according to the installation position information of the protection pipe. The lighting design protection tube generation method effectively reduces the drawing times of the protection tube, and therefore drawing efficiency of the protection tube is improved.

Description

Method, device and equipment for generating lighting design protection tube and storage medium

Technical Field

The present disclosure relates to the field of data processing technologies, and in particular, to a method, an apparatus, a device, and a storage medium for generating a lighting design protection tube.

Background

With the popularization and application of the BIM (Building Information Modeling) technology in recent years, more and more companies have introduced lighting design software based on the BIM concept. These software only provide the basic equipment layout, protecting the functions of the tube mapping, and do not fully take into account the complexity of the tube layout in the actual design.

The protection tube drawing method comprises the following steps that a designer places lighting equipment at a specified position in the process of using existing software, and then draws the protection tube in space by using a protection tube drawing function. During the drawing, the distance is raised to the protection tube of needs continuous calculation, and the level arranges the position, and the process is very loaded down with trivial details, and this just makes the protection tube drawing function that provides in adopting current lighting software carry out the drawing of protection tube, and speed is slower, and efficiency is lower.

Disclosure of Invention

In view of this, the present disclosure provides a method for generating a lighting design protection tube, which can effectively improve the drawing efficiency of the protection tube.

According to an aspect of the present application, there is provided a lighting design protection tube generation method including:

acquiring a building model and lighting equipment which needs to be arranged in the building model at present, and correspondingly installing the lighting equipment into the building model according to the installation mode of the lighting equipment;

conducting wire connection on the lighting devices according to the connection relation among the lighting devices;

configuring the laying mode of a protection pipe corresponding to different buildings in the building model based on the installation position of each lighting device in the building model;

generating a laying path of the protection pipe according to a connection wire between the lighting devices and a building located at an installation position of the lighting devices;

and calculating the installation position information of the protection pipe according to the building corresponding to the laying path and the laying mode, and drawing the protection pipe according to the installation position information of the protection pipe.

In one possible implementation manner, the correspondingly installing each lighting device into the building model according to the installation manner of each lighting device includes:

according to the installation mode of each lighting device, searching a building corresponding to the installation mode from the building model, and correspondingly installing the lighting device on the searched building;

wherein the mounting means comprises at least one of wall mounting, ceiling mounting and seating;

the building corresponding to the wall is at least one of a beam, a column and a wall surface, the building corresponding to the ceiling is a ceiling, and the building corresponding to the seat is a ground.

In one possible implementation manner, configuring the laying manner of the protection pipe corresponding to different buildings in the building model based on the installation position of each lighting device in the building model includes:

when the installation position is a wall, configuring the laying mode of the protection pipe corresponding to the wall in the building model into a concealed mode in the wall;

when the installation position is a ceiling, the laying mode of the protection pipe corresponding to the ceiling in the building model is configured into a concealed installation mode in the suspended ceiling;

when the installation position is a beam, arranging the laying mode of the protection pipe corresponding to the beam in the building model into a mode of along and crossing a roof truss;

when the installation position is a column, arranging the protection pipe in a manner corresponding to the column in the building model into a column-along and column-crossing manner;

when the installation position is a floor slab, configuring the laying mode of the protection tube corresponding to the floor slab in the building model into a suspended ceiling concealed installation mode;

when the installation position is a roof, configuring the laying mode of the protection pipe corresponding to the roof in the building model into a concealed mode in a roof top plate;

and when the installation position is the ground, the laying mode of the protection pipe corresponding to the ground in the building model is configured to be a ground and underfloor concealed mode.

In one possible implementation, generating a laying path of the protection pipe according to a connecting wire between the lighting devices and a building located at an installation position of the lighting devices includes:

acquiring a connecting wire between every two lighting devices, and adding a wire box in the connecting wire with a branch path to obtain a wire connecting path in the building model; the wire connecting path is a connecting channel of each lighting device on the space of the building model;

and obtaining a laying path of the protection pipe according to the wire connecting path and the building at the installation position of each lighting device.

In one possible implementation, the calculating of the installation position information of the protection pipe according to the building corresponding to the laying path and the laying method includes:

analyzing the type of each building passing along the laying path and acquiring the position information of each building; wherein the position information of each building comprises coordinate information of each building in the building model;

according to the type of each building obtained through analysis, determining a laying mode corresponding to the type of the building from the laying modes obtained in advance;

calculating according to the position information of each building and the determined laying mode and a preset rule to obtain the installation position information of the protection pipe on each building;

wherein the preset rules include installation positions of the protection pipes on different buildings.

According to another aspect of the present application, there is also provided a lighting design protection tube generation apparatus, including an equipment arrangement module, a wire drawing module, a base configuration module, and a protection tube generation module;

the equipment arrangement module is configured to obtain a building model and lighting equipment which needs to be arranged in the building model currently, and correspondingly install each lighting equipment into the building model according to the installation mode of each lighting equipment;

the wire drawing module is configured to wire-connect the lighting devices according to a connection relation between the lighting devices;

the basic configuration module is configured to configure the laying mode of the protection pipe corresponding to different buildings in the building model based on the installation position of each lighting device in the building model;

the protective tube generation module is configured to generate a laying path of the protective tube according to a connecting wire between the lighting devices and a building located at an installation position of the lighting devices;

the protection tube generation module is further configured to calculate installation position information of the protection tube according to the building corresponding to the laying path and the laying mode, and draw the protection tube according to the installation position information of the protection tube.

In one possible implementation, the device arrangement module includes a search submodule and an installation submodule;

the searching submodule is configured to search a building corresponding to the installation mode from the building model according to the installation mode of each lighting device;

the installation sub-module is configured to correspondingly install the lighting device on the searched building;

wherein the mounting means comprises at least one of wall mounting, ceiling mounting and seating;

the building corresponding to the wall is at least one of a beam, a column and a wall surface, the building corresponding to the ceiling is a ceiling, and the building corresponding to the seat is a ground.

In a possible implementation manner, the protection tube generating module includes a connection path obtaining sub-module and a laying path generating sub-module;

the connecting path obtaining sub-module is configured to obtain a connecting lead between every two lighting devices, and add a wire box to the connecting lead with a branch path to obtain a lead connecting path in the building model; the wire connecting path is a connecting channel of each lighting device on the space of the building model;

the laying path generation sub-module is configured to obtain a laying path of the protection pipe according to the wire connection path and a building located at an installation position of each lighting device.

According to an aspect of the present application, there is also provided a lighting design protection tube generating apparatus including:

a processor;

a memory for storing processor-executable instructions;

wherein the processor is configured to execute the executable instructions to implement any of the methods described above.

According to another aspect of the present application, there is also provided a non-transitory computer readable storage medium having stored thereon computer program instructions which, when executed by a processor, implement the method of any of the preceding.

According to the method for generating the lighting design protection tube, after a building model is obtained, the lighting devices are correspondingly installed in the building model according to the installation modes of the lighting devices which are required to be arranged in the building model at present, and then the laying path of the protection tube is generated based on various information (such as the connection relation among the lighting devices arranged in the building model, the laying modes of the protection tube in different buildings and the like) in the building model with the lighting devices arranged, so that the installation position information of the protection tube is calculated according to the generated laying path of the protection tube and the laying mode of the protection tube in each section of path, and finally the function of automatically drawing the protection tube is achieved. Compared with the mode of continuously calculating the lifting distance and the horizontal arrangement position of the protection tube in the process of drawing the protection tube in the related technology, the lighting design protection tube generation method can draw the protection tube meeting the standard only by calculating once, so that the drawing times of the protection tube are effectively reduced, and the drawing efficiency of the protection tube is improved.

Other features and aspects of the present disclosure will become apparent from the following detailed description of exemplary embodiments, which proceeds with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate exemplary embodiments, features, and aspects of the disclosure and, together with the description, serve to explain the principles of the disclosure.

Fig. 1 shows a flowchart of a lighting design protection tube generation method of an embodiment of the present application;

fig. 2 shows a block diagram of a lighting design protection tube generation device according to an embodiment of the present application;

fig. 3 shows a block diagram of a lighting design protection tube generation apparatus according to an embodiment of the present application.

Detailed Description

Various exemplary embodiments, features and aspects of the present disclosure will be described in detail below with reference to the accompanying drawings. In the drawings, like reference numbers can indicate functionally identical or similar elements. While the various aspects of the embodiments are presented in drawings, the drawings are not necessarily drawn to scale unless specifically indicated.

The word "exemplary" is used exclusively herein to mean "serving as an example, embodiment, or illustration. Any embodiment described herein as "exemplary" is not necessarily to be construed as preferred or advantageous over other embodiments.

Furthermore, in the following detailed description, numerous specific details are set forth in order to provide a better understanding of the present disclosure. It will be understood by those skilled in the art that the present disclosure may be practiced without some of these specific details. In some instances, methods, means, elements and circuits that are well known to those skilled in the art have not been described in detail so as not to obscure the present disclosure.

Fig. 1 shows a flowchart of a lighting design protection tube generation method of the present application. Referring to fig. 1, the method of the present application includes step S100 of obtaining a building model and lighting devices that need to be arranged in the building model currently, and installing the lighting devices into the building model correspondingly according to installation manners of the lighting devices. Here, it should be noted that the building model may be a three-dimensional model constructed for a scene by using any three-dimensional modeling software. Meanwhile, it can be understood by those skilled in the art that the lighting device may be various lighting apparatuses, such as: the device may be a lamp, a socket, or other devices, and is not particularly limited herein. It should also be noted that different lighting devices may be mounted differently. The installation manner here mainly includes the installation position of the lighting device. And step S200, conducting wire connection on the lighting devices according to the connection relation among the lighting devices. Here, the connection relationship between the lighting apparatuses includes whether or not there is a connection between the plurality of lighting apparatuses and a connection manner when there is a connection relationship. The connection means may include at least one of parallel connection and series connection.

In step S300, based on the installation position of each lighting device in the building model, the installation mode of the protection pipe corresponding to different buildings in the building model is configured. That is, the installation carrier of the protective pipe for each lighting apparatus (i.e., the building to which the protective pipe for the lighting apparatus is installed in the building model) can be known from the installation position of the lighting apparatus in the building model, and thus the corresponding installation method is configured according to different installation carriers. Step S400 is to generate a laying path of the protective pipe from the connection wires between the lighting devices and the building located around the installation position of the lighting devices. After the additional laying path of the protection pipe is generated, the installation position information of the protection pipe is calculated according to the building and the laying mode corresponding to the generated laying path, and the protection pipe is drawn according to the installation position information of the protection pipe in step S500.

Therefore, according to the lighting design protection tube generation method, after the building model is obtained, the lighting devices are correspondingly installed in the building model according to the installation modes of the lighting devices which are required to be arranged in the building model at present, and then the laying path of the protection tube is generated based on various information (such as the connection relation among the lighting devices arranged in the building model, the laying modes of the protection tube in different buildings and the like) in the building model with the lighting devices arranged, so that the installation position information of the protection tube is calculated according to the generated laying path of the protection tube and the laying mode of the protection tube in each section of path, and finally, the function of automatically drawing the protection tube is realized. Compared with the mode of continuously calculating the lifting distance and the horizontal arrangement position of the protection tube in the process of drawing the protection tube in the related technology, the lighting design protection tube generation method can draw the protection tube meeting the standard only by calculating once, so that the drawing times of the protection tube are effectively reduced, and the drawing efficiency of the protection tube is improved.

In one possible implementation manner, when the lighting devices are correspondingly installed in the building model according to the installation manner of the lighting devices, the following manner can be adopted. Specifically, a building corresponding to the installation mode is searched from the building model according to the installation mode of each lighting device, and the lighting device is correspondingly installed on the searched building. Here, it should be noted that the installation manner of the lighting device includes at least one of wall mounting, ceiling mounting, and seating. Different installation modes correspond to different buildings. Such as: the building corresponding to the wall is at least one of a beam and a column, the building corresponding to the ceiling is a ceiling, and the building corresponding to the seat is a ground.

For example, when the lighting device is installed on the wall, a building corresponding to the wall (i.e., at least one of a beam, a column, and a wall in the building model) is searched from the building model according to the installation manner of the wall, and then the id of the lighting device is matched with the id of the searched building to determine the building corresponding to the lighting device (e.g., the building determined by matching is a certain wall in the building model), and finally the lighting device is installed on the building successfully matched according to the matching result.

Therefore, when the lighting equipment is arranged, the building corresponding to the installation mode of the lighting equipment is searched from the building model according to the installation mode of the lighting equipment, so that the lighting equipment finally arranged in the building model can be installed at an accurate position, and an accurate basis is provided for drawing the protection pipe later.

It should be noted that the installation mode of each lighting device is recorded in the database together with each lighting device, so that when the installation mode of each lighting device is acquired, relevant data can be directly read from the data stored in the database. The method is simple and easy to realize.

Further, in the lighting device protection tube generation method of the present application, after each lighting device is correspondingly installed in the building model using the device placement function, the placed lighting devices may be connected to determine the connection lines of the lighting devices in the building model. Here, when the wire connection of each lighting device is performed, the wire connection may be performed by directly using the wire drawing function.

Specifically, when the wires are connected to the lighting devices, the wires can be drawn directly according to the connection relationship between the lighting devices. The connection relation between the lighting devices is stored in the design drawing, so that the connection relation between the lighting devices can be directly obtained from the design drawing, and the data reading mode is simple and convenient.

After the lighting devices are arranged in the building model by using the device arrangement function and the wiring drawing function is used for drawing the wiring of the lighting devices with connection relation to obtain the connection paths of the lighting devices in the building model, the protective pipes can be drawn.

In one possible implementation, since the protection tube has different laying modes in different buildings, the laying modes of the protection tube in different buildings in the building model need to be configured before drawing the protection tube. Specifically, the configuration process may use a basic configuration function to configure the laying mode of the protection pipe corresponding to different buildings in the building model based on the installation position of each lighting device in the building model.

For example, referring to table 1, the method of laying the protection pipe corresponding to several different buildings is listed.

TABLE 1 laying mode of protection pipe corresponding to different buildings in building model

Wall with a plurality of walls	Wall built-in
		Ceiling board	Concealed installation in suspended ceiling
Beam	Roof truss
		Column	Along and across column
Floor slab	Concealed installation in suspended ceiling
		Roof with a plurality of layers of material	Roof top plate built-in
Ground surface	Underground floor

As can be seen from table 1, when the installation position of the lighting apparatus is a wall, the installation manner of the protective pipe provided at the installation position of the lighting apparatus may be configured to be concealed in the wall. That is, the protection pipe is arranged in a wall concealed manner corresponding to the manner of laying the wall in the building model.

When the installation position of the lighting device is a ceiling, the protection pipe provided at the installation position of the lighting device may be installed in a manner of being hidden in the ceiling. Namely, the protection pipe is configured to be a ceiling concealed installation mode corresponding to the installation mode of the ceiling in the building model.

When the installation position of the lighting device is a beam, the protective pipe provided at the installation position of the lighting device may be laid in any one of a manner along and a manner across the roof truss. That is, the protective pipe is arranged along and across the roof truss in accordance with the manner of laying the beam in the building model.

When the installation position of the lighting apparatus is a column, the laying manner of the protection pipe provided at the installation position of the lighting apparatus may be configured to be any one of along and across the column. That is, the protective pipe is arranged along and across the column in accordance with the manner of laying the column in the building model.

When the installation position of the lighting device is a floor, the protection pipe arranged at the installation position of the lighting device may be arranged to be concealed in the ceiling. Namely, the protection pipe is configured to be a ceiling concealed installation mode corresponding to the laying mode of the floor in the building model.

When the installation position of the lighting device is a roof, the protection pipe provided at the installation position of the lighting device may be laid in a manner of being hidden in the roof panel. That is, the protection pipe is arranged in a manner corresponding to the manner of laying the roof in the building model, as a concealed manner in the roof panel.

When the installation position of the lighting apparatus is the ground, the laying manner of the protection pipe provided at the installation position of the lighting apparatus may be configured to be either one of the ground and the underfloor concealed. That is, the protection pipe is arranged in a manner corresponding to the manner of laying the ground in the building model, and in a manner of embedding the ground and the underfloor.

Therefore, according to the lighting design protection tube generation method, the protection tubes are firstly configured in the laying modes of different buildings before the protection tubes are drawn, so that the protection tubes are drawn according to the pre-configured laying mode in the subsequent drawing of the protection tubes, the drawing accuracy of the protection tubes is further ensured, and the reliability of the lighting equipment protection tube generation method is effectively improved.

Further, after the arrangement of the information necessary for drawing the protection pipe is performed by any of the above-described methods, the laying path of the protection pipe can be generated from the connection wires between the respective lighting apparatuses and the building located at the installation position of the respective lighting apparatuses. The following can be implemented in generating the laying path of the protective tube.

That is, first, a connection wire between every two of the lighting devices is acquired, and a wire box is added to the connection wire in which the branch path exists, resulting in a wire connection path in the building model. Wherein, as will be understood by those skilled in the art, the wire connection path is a connection channel of each lighting device on the space of the architectural model. That is, by adding the line boxes at corresponding positions in the connection wires where the branch paths exist, further optimization of the connection paths of the lighting devices already arranged in the building model is achieved, so that the laying path of the protection pipe generated is more accurate. After the connection paths of the lighting devices arranged in the building model are optimized, the laying paths of the protection pipes can be obtained according to the wire connection paths and the buildings located at the installation positions of the lighting devices. Here, it is understood by those skilled in the art that the laying path of the protection pipe refers to a laying path of the protection pipe on a space in the building model.

For example, a lighting device that has been arranged in a building model includes a switch and a set of lights. Wherein, a switch controls a group of lamps, the installation position of the switch is on the wall, and the installation position of the lamps is on the ceiling. Here, according to the installation position of the switch and the installation position of the lamp, and the connection relationship between the switch and the lamp, a wire connection path of the switch and the lamp in the building model is determined. And then, according to the wire connecting path, calculating that the protective tube firstly reaches the upper surface of the ceiling along the wall, and then drawing a horizontal protective tube in the ceiling, wherein the path of the protective tube in the horizontal direction refers to the drawing position of the wire between the lamps. If the bifurcation is occurred, a wire box is added at a proper position to process the branch of the protection tube. In this way, the path of the protective tubes of the switches and lamps already arranged in the building model is finally obtained.

After the laying path of the protection pipe is generated, the installation position information of the protection pipe can be calculated according to the building and the laying mode corresponding to the laying path, and therefore the corresponding protection pipe can be automatically drawn according to the installation position information of each section of protection pipe.

When the installation position information of the protection pipe is calculated according to the building and the laying mode corresponding to the laying path, the type of each building passing along the laying path can be analyzed, and the position information of each building can be obtained. Here, it should be noted that, in the method of the present application, the position information of each building includes coordinate information of each building in the building model.

Then, the type of each building is analyzed, and a laying method corresponding to the type of the building is determined from laying methods obtained in advance. That is, for different buildings on the laying route, a laying method matching the buildings on the different route is selected from the various laying methods arranged previously. And then, calculating according to the position information of each building and the determined laying mode and according to a preset rule to obtain the installation position information of the protection pipe on each building. It should be noted that the preset rule includes the installation positions of the protection pipes on different buildings. That is, when the protection pipe is installed in a different building, the protection pipe is located in the specific location information of the building.

For example, the switch is on a wall, the laying path of the protection tube is drawn upwards along the wall or downwards along the wall, and the preset rule is that the protection tube is drawn at a preset depth in the wall. That is, the protection pipe is installed at a predetermined depth in the wall. The following steps are repeated: the lamps are arranged on the ceiling, the laying path of the section of the protection pipe is horizontally drawn in the ceiling, and the protection pipe is installed at a preset height from the ceiling according to a preset rule.

More specifically, the preset rule includes that the installation position corresponding to the concealed installation in the wall in the laying mode is 10mm in the wall, and then for the road section in which the laying mode is concealed in the wall in the laying path of the protection tube, the installation position of the protection tube at the road section concealed in the wall can be calculated to be 10mm inward offset according to the wall surface through the preset rule.

It should be noted that different building models correspond to different preset rules, and the preset rules can be flexibly set according to actual conditions, and are not specifically limited here. Meanwhile, preset rules can be directly stored in the database, so that data can be read at any time in the drawing process of the protective tube, and the corresponding preset rules can be updated in real time when the building model is changed.

From this, through the position information and the mode of laying confirmed of the building of different road sections department in the route of laying the protection tube, carry out the calculation of the mounted position of protection tube according to predetermineeing the rule for the mounted position of protection tube is more accurate, and this has just so avoided the protection tube to draw the condition that position error appears further, thereby has further improved the efficiency that the protection tube was drawn.

Correspondingly, based on any one of the lighting design protection tube generation methods, the application also provides a lighting design protection tube generation device. Since the working principle of the illumination design protection tube generation device of the present application is the same as or similar to that of the illumination design protection tube generation method of the present application, repeated descriptions are omitted.

Referring to fig. 2, the lighting design protective tube generating apparatus 100 of the present application includes an equipment arranging module 110, a wire drawing module 120, a base configuration module 130, and a protective tube generating module 140. The device arrangement module 110 is configured to obtain a building model and lighting devices that need to be arranged in the building model currently, and install the lighting devices into the building model correspondingly according to installation manners of the lighting devices. And a wire drawing module 120 configured to wire-connect the lighting apparatuses according to a connection relationship between the lighting apparatuses. And a base configuration module 130 configured to configure the laying mode of the protection pipe corresponding to different buildings in the building model based on the installation position of each lighting device in the building model. A protective pipe generation module 140 configured to generate a laying path of a protective pipe according to a connection wire between the respective lighting apparatuses and a building located at an installation position of the respective lighting apparatuses. The protective tube generation module 140 is further configured to calculate installation position information of the protective tube according to the building and the installation mode corresponding to the installation path, and draw the protective tube according to the installation position information of the protective tube.

In one possible implementation, the device placement module 110 includes a search sub-module and an installation sub-module (not shown in the figures). And the searching sub-module is configured to search a building corresponding to the installation mode from the building model according to the installation mode of each lighting device. And the mounting sub-module is configured to correspondingly mount the lighting device on the searched building. Wherein, the mounting mode comprises at least one of wall mounting, ceiling mounting and seat mounting. The building corresponding to the wall is at least one of a beam, a column and a wall surface, the building corresponding to the ceiling is a ceiling, and the building corresponding to the seat is a ground.

In one possible implementation, protection tube generation module 140 includes a connection path acquisition sub-module and a laying path generation sub-module (not shown in the figures). A connection path acquisition sub-module configured to acquire a connection wire between each two lighting devices, and add a wire box to the connection wire in which the branch path exists, resulting in a wire connection path in the building model; the wire connection path is a connection channel of each lighting device on the space of the building model. A laying path generation sub-module configured to obtain a laying path of the protection pipe from the wire connection path and the building located at the installation position of each lighting device.

Still further, according to another aspect of the present disclosure, there is also provided a lighting design protection tube generating apparatus 200. Referring to fig. 3, the lighting design protection tube generating apparatus 200 according to the embodiment of the present disclosure includes a processor 210 and a memory 220 for storing instructions executable by the processor 210. Wherein the processor 210 is configured to execute the executable instructions to implement any of the lighting design protection tube generation methods described above.

Here, it should be noted that the number of the processors 210 may be one or more. Meanwhile, in the lighting design protection tube generating apparatus 200 of the embodiment of the present disclosure, an input device 230 and an output device 240 may be further included. The processor 210, the memory 220, the input device 230, and the output device 240 may be connected via a bus, or may be connected via other methods, which is not limited in detail herein.

The memory 220, which is a computer-readable storage medium, may be used to store software programs, computer-executable programs, and various modules, such as: the lighting design protection tube generation method of the embodiment of the disclosure corresponds to a program or a module. The processor 210 executes various functional applications and data processing of the lighting design protection tube generating apparatus 200 by running software programs or modules stored in the memory 220.

The input device 230 may be used to receive an input number or signal. Wherein the signal may be a key signal generated in connection with user settings and function control of the device/terminal/server. The output device 240 may include a display device such as a display screen.

According to another aspect of the present disclosure, there is also provided a non-transitory computer readable storage medium having stored thereon computer program instructions, which when executed by the processor 210, implement any of the lighting design protection tube generation methods described above.

Having described embodiments of the present disclosure, the foregoing description is intended to be exemplary, not exhaustive, and not limited to the disclosed embodiments. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments. The terms used herein were chosen in order to best explain the principles of the embodiments, the practical application, or technical improvements to the techniques in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein.

Claims (10)

1. A lighting design protection tube generation method, comprising:

acquiring a building model and lighting equipment which needs to be arranged in the building model at present, and correspondingly installing the lighting equipment into the building model according to the installation mode of the lighting equipment;

conducting wire connection on the lighting devices according to the connection relation among the lighting devices;

configuring the laying mode of a protection pipe corresponding to different buildings in the building model based on the installation position of each lighting device in the building model;

generating a laying path of the protection pipe according to a connection wire between the lighting devices and a building located at an installation position of the lighting devices;

and calculating the installation position information of the protection pipe according to the building corresponding to the laying path and the laying mode, and drawing the protection pipe according to the installation position information of the protection pipe.

2. The method of claim 1, wherein installing each lighting device into the building model according to the installation manner of each lighting device comprises:

according to the installation mode of each lighting device, searching a building corresponding to the installation mode from the building model, and correspondingly installing the lighting device on the searched building;

wherein the mounting means comprises at least one of wall mounting, ceiling mounting and seating;

the building corresponding to the wall is at least one of a beam, a column and a wall surface, the building corresponding to the ceiling is a ceiling, and the building corresponding to the seat is a ground.

3. The method of claim 1, wherein configuring the manner of laying protection pipes corresponding to different buildings in the building model based on the installation positions of the lighting devices in the building model comprises:

when the installation position is a wall, configuring the laying mode of the protection pipe corresponding to the wall in the building model into a concealed mode in the wall;

when the installation position is a ceiling, the laying mode of the protection pipe corresponding to the ceiling in the building model is configured into a concealed installation mode in the suspended ceiling;

when the installation position is a beam, arranging the laying mode of the protection pipe corresponding to the beam in the building model into a mode of along and crossing a roof truss;

when the installation position is a column, arranging the protection pipe in a manner corresponding to the column in the building model into a column-along and column-crossing manner;

when the installation position is a floor slab, configuring the laying mode of the protection tube corresponding to the floor slab in the building model into a suspended ceiling concealed installation mode;

when the installation position is a roof, configuring the laying mode of the protection pipe corresponding to the roof in the building model into a concealed mode in a roof top plate;

and when the installation position is the ground, the laying mode of the protection pipe corresponding to the ground in the building model is configured to be a ground and underfloor concealed mode.

4. A method according to any one of claims 1 to 3, wherein generating a laying path of the protective pipe from connecting wires between the lighting devices and the building at the installation location of the lighting devices comprises:

acquiring a connecting wire between every two lighting devices, and adding a wire box in the connecting wire with a branch path to obtain a wire connecting path in the building model; the wire connecting path is a connecting channel of each lighting device on the space of the building model;

and obtaining a laying path of the protection pipe according to the wire connecting path and the building at the installation position of each lighting device.

5. The method according to any one of claims 1 to 3, wherein calculating the installation position information of the protection pipe based on the building corresponding to the laying path and the laying method includes:

analyzing the type of each building passing along the laying path and acquiring the position information of each building; wherein the position information of each building comprises coordinate information of each building in the building model;

according to the type of each building obtained through analysis, determining a laying mode corresponding to the type of the building from the laying modes obtained in advance;

calculating according to the position information of each building and the determined laying mode and a preset rule to obtain the installation position information of the protection pipe on each building;

wherein the preset rules include installation positions of the protection pipes on different buildings.

6. The device for generating the protection tube for the lighting design is characterized by comprising an equipment arrangement module, a lead drawing module, a basic configuration module and a protection tube generation module;

the equipment arrangement module is configured to obtain a building model and lighting equipment which needs to be arranged in the building model currently, and correspondingly install each lighting equipment into the building model according to the installation mode of each lighting equipment;

the wire drawing module is configured to wire-connect the lighting devices according to a connection relation between the lighting devices;

the basic configuration module is configured to configure the laying mode of the protection pipe corresponding to different buildings in the building model based on the installation position of each lighting device in the building model;

the protective tube generation module is configured to generate a laying path of the protective tube according to a connecting wire between the lighting devices and a building located at an installation position of the lighting devices;

the protection tube generation module is further configured to calculate installation position information of the protection tube according to the building corresponding to the laying path and the laying mode, and draw the protection tube according to the installation position information of the protection tube.

7. The apparatus of claim 6, wherein the device placement module comprises a search submodule and a mounting submodule;

the searching submodule is configured to search a building corresponding to the installation mode from the building model according to the installation mode of each lighting device;

the installation sub-module is configured to correspondingly install the lighting device on the searched building;

wherein the mounting means comprises at least one of wall mounting, ceiling mounting and seating;

the building corresponding to the wall is at least one of a beam, a column and a wall surface, the building corresponding to the ceiling is a ceiling, and the building corresponding to the seat is a ground.

8. The apparatus of claim 6 or 7, wherein the protection tube generation module comprises a connection path acquisition sub-module and a laying path generation sub-module;

the connecting path obtaining sub-module is configured to obtain a connecting lead between every two lighting devices, and add a wire box to the connecting lead with a branch path to obtain a lead connecting path in the building model; the wire connecting path is a connecting channel of each lighting device on the space of the building model;

the laying path generation sub-module is configured to obtain a laying path of the protection pipe according to the wire connection path and a building located at an installation position of each lighting device.

9. An illumination design protection tube generating apparatus, comprising:

a processor;

a memory for storing processor-executable instructions;

wherein the processor is configured to implement the method of any one of claims 1 to 5 when executing the executable instructions.

10. A non-transitory computer readable storage medium having computer program instructions stored thereon, wherein the computer program instructions, when executed by a processor, implement the method of any of claims 1 to 5.

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