A high-efficiency design and implementation system for a sample building project
By integrating the design subsystem, construction management subsystem, and construction subsystem, the problems of manual drawing and multiple revisions in the design of model buildings were solved, enabling efficient collaborative work between model building design and construction, improving efficiency and reducing costs.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- SUZHOU SUDA ARCHITECTURAL PLANNING & DESIGN CO LTD
- Filing Date
- 2024-09-25
- Publication Date
- 2026-07-10
AI Technical Summary
The existing model building design and implementation plan relies on tedious manual drawing and multiple design draft revisions, lacking standardization and modular application, which means that each project needs to be designed from scratch, resulting in low efficiency and high change costs.
By integrating design, construction management, and building subsystems, including storage, intelligent algorithm, visualization, resource management, and automated construction equipment, it achieves high-precision scanning, real-time monitoring, and automated construction, and supports cloud synchronization.
This enabled highly efficient collaboration between the design and construction of the model building, improving design and construction efficiency, ensuring timely and high-quality completion, and reducing change costs.
Smart Images

Figure CN119249565B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of model building design, and more specifically to an efficient design and implementation system for model building projects. Background Technology
[0002] A model apartment is a packaged product for a commercial property and a reference example for potential buyers regarding its interior design. The quality of its decoration directly affects buyers' first impression of the property and is a crucial factor in the sales process. Therefore, as a reference example for many homebuyers, real estate developers are paying increasing attention to the design and decoration of the interior of model apartments. Since model apartments are for showcasing the exterior appearance of the property, there are no mandatory structural requirements, and temporary structures can be quickly erected according to project requirements.
[0003] Existing model building design implementation plans rely on tedious manual drawing and multiple revisions and finalizations of design drafts. During the design and subsequent construction process, if adjustments are needed, such as design changes or material replacements, multiple stages will need to be rearranged and coordinated, increasing change costs. Furthermore, due to the lack of standardization and modularization, each project needs to be designed from scratch before subsequent construction, making it impossible to quickly replicate or adjust existing design experience and resources, further reducing efficiency and slowing down the overall design progress. Summary of the Invention
[0004] The technical problem to be solved by the present invention is to provide an efficient design and implementation system for model building projects, which can achieve high-precision scanning over a large area.
[0005] The technical solution of this invention to solve the above-mentioned technical problems is as follows: A high-efficiency design and implementation system for model building projects, comprising:
[0006] The design subsystem is used to assist in the design and storage of the decoration design schemes of the model building. The design subsystem includes a storage module, a design template library and an intelligent algorithm module. The design template library integrates design templates related to the model building. The storage module is used to store the design schemes. The intelligent algorithm module is also connected to a visualization module for projecting and displaying the decoration design schemes in the model building.
[0007] The construction management subsystem is used to monitor the construction site in real time and track the construction progress. The construction management subsystem includes a resource management module for recording the usage of building materials and a progress statistics module.
[0008] The construction subsystem is used to assist in the construction of the model building. The rapid construction module includes a pre-assembly system and an auxiliary construction module. The pre-assembly system is used to pre-assemble commonly used building materials before they enter the model building. The auxiliary construction module controls and drives automated construction equipment.
[0009] Preferably, the visualization module includes a scanning module, a demonstration module, and a projection module. The scanning module is used to scan the internal and external structure of the model building. The demonstration module is used to read the design scheme in the storage module. The projection module projects the design scheme read by the demonstration module according to the model building structure scanned by the scanning module.
[0010] Preferably, the intelligent algorithm module includes:
[0011] The optimization analysis unit is used to optimize the design scheme.
[0012] The user interface enables designers to interact with the design subsystem.
[0013] Preferably, the resource management module further includes:
[0014] The inventory monitoring unit is used to monitor the inventory of building materials in real time and remind the designer to make purchases when the inventory falls below a preset threshold.
[0015] The loss calculation unit reads data from the progress statistics module and the resource management module to understand the construction progress and the usage of building materials, and calculates and predicts the loss of building materials.
[0016] Preferably, the resource management module further includes:
[0017] A task allocation unit, which allocates construction tasks to corresponding construction teams or workers according to the construction plan;
[0018] An anomaly handling unit is used to monitor and record abnormal situations during the construction process, including but not limited to schedule delays and quality problems, and automatically generate alarm information so that timely countermeasures can be taken.
[0019] Preferably, the auxiliary construction module includes:
[0020] The automated path planning unit is used to automatically plan the movement path of automated assembly equipment based on the structure and construction requirements of the model building.
[0021] The safety monitoring unit is used to monitor the equipment's operating status and the surrounding environment in real time during the automated setup process.
[0022] Preferably, it also includes a cloud synchronization module, which is used to upload data from the design subsystem, construction management subsystem and construction subsystem to the cloud server in real time, so as to realize remote monitoring, data sharing and collaborative work.
[0023] The beneficial effects of this invention are that by integrating design templates, intelligent algorithms, real-time monitoring, automated construction, and cloud synchronization modules, it achieves comprehensive and efficient collaborative work from design to construction and building, significantly improving work efficiency and ensuring that the model building project is completed on time and with high quality. Attached Figure Description
[0024] Figure 1 This is an overall structural block diagram of a high-efficiency design and implementation system for model building projects according to the present invention;
[0025] Figure 2 This is a schematic diagram showing the connection relationship between the design subsystem and the visualization module of the efficient design and implementation system for model building projects according to the present invention;
[0026] Figure 3 This is a structural block diagram of the construction management subsystem of the efficient design and implementation system for model building projects according to the present invention;
[0027] Figure 4 This is a structural block diagram of the construction subsystem of a high-efficiency design and implementation system for model building projects according to the present invention;
[0028] Figure 5 This is a schematic diagram showing the connection between the design subsystem and the cloud synchronization module of the efficient design and implementation system for model building projects according to the present invention.
[0029] The attached diagram lists the components represented by each number as follows:
[0030] 1. Design Subsystem; 11. Storage Module; 12. Design Template Library; 13. Intelligent Algorithm Module; 2. Construction Management Subsystem; 21. Resource Management Module; 22. Progress Statistics Module; 3. Visualization Module; 31. Scanning Module; 311. 3D Scanner; 32. Demonstration Module; 33. Projection Module; 331. Smart Screen; 332. Projector; 4. Construction Subsystem; 41. Pre-assembly System; 42. Auxiliary Construction Module; 5. Cloud Synchronization Module. Detailed Implementation
[0031] The principles and features of the present invention are described below with reference to the accompanying drawings. The examples given are only for explaining the present invention and are not intended to limit the scope of the present invention.
[0032] like Figure 1 , Figure 2 , Figure 3 , Figure 4 and Figure 5As shown, a high-efficiency design and implementation system for model building projects includes:
[0033] Design subsystem 1 is used to assist in the design and store the decoration design scheme of the model building. Design subsystem 1 includes storage module 11, design template library 12 and intelligent algorithm module 13. Design template library 12 integrates design templates related to the model building. Storage module 11 is used to store design schemes. Intelligent algorithm module 13 is also connected to visualization module 3, which is used to project and display the decoration design scheme in the model building.
[0034] Construction management subsystem 2 is used to monitor the construction site in real time and track the construction progress. Construction management subsystem 2 includes a resource management module 21 for recording the use of building materials and a progress statistics module 22.
[0035] Construction subsystem 4 is used to assist in the construction of the model building. The rapid construction module includes a pre-assembly system 41 and an auxiliary construction module 42. The pre-assembly system 41 is used to pre-assemble commonly used building materials before they enter the model building. The auxiliary construction module 42 controls and drives automated construction equipment.
[0036] In this embodiment, the visualization module 3 includes a scanning module 31, a demonstration module 32, and a projection module 33. The scanning module 31 is used to scan the internal and external structure of the model building and store the internal and external structure in the storage module 11. The demonstration module 32 is used to read the design scheme in the storage module 11. The intelligent algorithm module 13 automatically compares the scanned internal and external structure with the design scheme and notifies the designer.
[0037] The projection module 33 projects the design scheme read by the demonstration module 32 based on the sample building structure scanned by the scanning module 31, and displays it through the smart screen 331 or the projector 332.
[0038] In this embodiment, the intelligent algorithm module 13 includes:
[0039] The optimization analysis unit is used to optimize the design scheme.
[0040] The user interface enables designers to interact with the design subsystem 1.
[0041] In this embodiment, the resource management module 21 further includes:
[0042] The inventory monitoring unit is used to monitor the inventory of building materials in real time and remind the designer to make purchases when the inventory falls below a preset threshold.
[0043] The loss calculation unit reads data from the progress statistics module 22 and the resource management module 21 to understand the construction progress and the usage of building materials. The loss calculation unit calculates and predicts the loss of building materials.
[0044] In this embodiment, the resource management module 21 further includes:
[0045] The task allocation unit assigns construction tasks to the corresponding construction teams or workers according to the construction plan.
[0046] The anomaly handling unit is used to monitor and record abnormal situations during the construction process, including but not limited to schedule delays and quality problems, and automatically generate alarm information so that timely countermeasures can be taken.
[0047] In this embodiment, the auxiliary construction module 42 includes:
[0048] The automated path planning unit is used to automatically plan the movement path of automated assembly equipment based on the structure and construction requirements of the model building.
[0049] The safety monitoring unit is used to monitor the equipment's operating status and the surrounding environment in real time during the automated setup process.
[0050] In this embodiment, a cloud synchronization module 5 is also included, which is used to upload data from the design subsystem 1, construction management subsystem 2 and construction subsystem 4 to the cloud server in real time, so as to realize remote monitoring, data sharing and collaborative work. Designers, construction managers and construction teams can access data anytime and anywhere, improving communication efficiency and decision response speed.
[0051] Designers interact with the intelligent algorithm module 13 through a user interface, using ready-made templates from the design template library 12 or designing the decoration scheme of the model building from scratch. Design schemes and historical schemes are stored in the storage module 11. The optimization analysis unit in the intelligent algorithm module 13 automatically evaluates and optimizes the design schemes to ensure they are practical and aesthetically pleasing. The user interface provides an intuitive operation interface, facilitating real-time interaction between designers and the design subsystem 1. Once the design scheme is finalized, the visualization module 3 uses the scanning module 31 to accurately scan the internal and external structure of the model building. The demonstration module 32 reads the design scheme from the storage module 11, and the projection module 33 projects the design scheme according to the actual structure of the model building, allowing designers and clients to intuitively see the final effect. Before construction, the resource management module 21 monitors the inventory of building materials in real time through the inventory monitoring unit. When the inventory falls below a preset threshold, it alerts the client to purchase more materials. The loss calculation unit predicts and calculates material loss based on the construction progress and building material usage to optimize resources. The configuration and task allocation unit assigns specific construction tasks to corresponding construction teams or workers according to the construction plan to ensure orderly construction. During the formal construction phase, the construction management subsystem 2 monitors the construction site in real time and tracks the construction progress through the progress statistics module 22 to ensure the project progresses on time. At the same time, the resource management module 21 continuously monitors the material usage and works in conjunction with the loss calculation unit to adjust the material supply plan in a timely manner. During the construction process, the pre-assembly system 41 prompts the pre-assembly of commonly used building materials before the building materials enter the model building, reducing on-site assembly time and speeding up the construction progress. An anomaly handling unit is set up in the construction and decoration site to monitor abnormal situations during the construction process, such as progress delays and quality problems, and automatically records the generated information so that timely countermeasures can be taken to reduce losses. During the construction of the model building, the automated path planning unit automatically plans the movement path of the automated assembly equipment according to the structure and construction requirements of the model building to improve construction efficiency. The safety monitoring unit monitors the equipment operation status and the surrounding environment in real time to ensure construction safety.
[0052] The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A high-efficiency design and implementation system for model building projects, characterized in that, include: Design subsystem (1), the design subsystem (1) is used to assist in designing and storing the decoration design scheme of the model building. The design subsystem (1) includes a storage module (11), a design template library (12) and an intelligent algorithm module (13). The design template library (12) integrates design templates related to the model building. The storage module (11) is used to store the design scheme. The intelligent algorithm module (13) is also connected to a visualization module (3) for projecting and displaying the decoration design scheme in the model building. Construction management subsystem (2) is used to monitor the construction site in real time and track the construction progress. The construction management subsystem (2) includes a resource management module (21) for recording the use of building materials and a progress statistics module (22). Construction subsystem (4) is used to assist in the construction of model building. The rapid construction module includes a pre-assembly system (41) and an auxiliary construction module (42). The pre-assembly system (41) is used to pre-assemble common building materials before they enter the model building. The auxiliary construction module (42) controls and drives automated construction equipment. The visualization module (3) includes a scanning module (31), a demonstration module (32), and a projection module (33). The scanning module (31) is used to scan the model building. The demonstration module (32) is used to read the design scheme in the storage module (11). The scanning module (31) is used to scan the internal and external structure of the model building and store the internal and external structure in the storage module (11). The intelligent algorithm module (13) automatically compares the scanned internal and external structure with the design scheme in the storage module (11) and notifies the designer.
2. The efficient design and implementation system for model building projects according to claim 1, characterized in that: The projection module (33) projects the design scheme read by the demonstration module (32) based on the sample building structure scanned by the scanning module (31), and displays it through the smart screen (331) or projector (332).
3. The efficient design and implementation system for model building projects according to claim 1, characterized in that: The intelligent algorithm module (13) has: The optimization analysis unit is used to optimize the design scheme. User interaction interface, which enables designers to interact with the design subsystem (1).
4. The efficient design and implementation system for model building projects according to claim 1, characterized in that: The resource management module (21) has: The inventory monitoring unit is used to monitor the inventory of building materials in real time and remind the designer to make purchases when the inventory falls below a preset threshold. The loss calculation unit reads data from the progress statistics module (22) and the resource management module (21) to understand the construction progress and the use of building materials. The loss calculation unit calculates and predicts the loss of building materials.
5. The efficient design and implementation system for a model building project according to claim 1, characterized in that: The resource management module (21) also has: A task allocation unit, which allocates construction tasks to corresponding construction teams or workers according to the construction plan; An anomaly handling unit is used to monitor and record abnormal situations during the construction process, including progress delays and quality problems, and automatically generate alarm information so that timely countermeasures can be taken.
6. The efficient design and implementation system for a model building project according to claim 1, characterized in that: The auxiliary construction module (42) includes: The automated path planning unit is used to automatically plan the movement path of automated assembly equipment based on the structure and construction requirements of the model building. The safety monitoring unit is used to monitor the equipment's operating status and the surrounding environment in real time during the automated setup process.
7. The efficient design and implementation system for a model building project according to claim 1, characterized in that: It also includes a cloud synchronization module (5), which is used to upload data from the design subsystem (1), construction management subsystem (2) and construction subsystem (4) to the cloud server in real time, so as to realize remote monitoring, data sharing and collaborative work.