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文章出处:Technology|阅读量:426|发表时间:2021-03-05
With the advancement of technology and science, the automation of routine laboratory work has reduced the physical footprint of the laboratory, and as more laboratory work can be completed and analyzed with technology, these changes will continue in the next few years. Growth means that scientists will no longer need to spend a lot of time in the laboratory. They will have more time for cooperation and idea-based work projects. The future laboratory must be intelligently operated and scientifically documented. Rationalize the place. This requires experimental design and builders to consider issues more comprehensively in the preliminary planning.
CEIDI believes that the digital laboratory helps to record the experimental process in more detail. In actual operation, the users also reflect that when the files are customized according to their needs, and can be accessed through the network and shared with colleagues, project management is easy too much. On some occasions, digital devices can also help researchers find some correlations from stored data in an orderly manner, or extract results.
In the process of building a “digital laboratory” and then moving towards “intelligent manufacturing”, it is crucial to realize the “digital delivery” of engineering projects. Digital delivery is not only an important symbol of designing digital transformation, but also the only way to help owners receive and manage data assets and provide a data foundation for the construction of digital factories.
Take the construction of a laboratory in CEIDI Xidi as an example. We apply BIM technology to a purification project. The designer first surveys the geographical environment of the project site and communicates with the project staff, and then uses BIM technology to integrate the information of the design drawings into In an intuitive 3D model, the creation, management, and sharing of this project can be carried out on the computer virtually, and it can also automatically count the engineering quantity and generate the material table, so as to realize the visualization and fine management of the project. When connecting with the project team for management, the project team’s personnel can intuitively feel the rationality of the partitions and experience the effects of future laboratory completion through VR technology. Both parties can also directly conduct evaluations and inspections of the laboratory through the mobile APP many times, and can find out in advance possible failures or risks in the future, and carry out investigations and solutions in advance.
In the stage of construction, the wide application of digital BIM technology has obvious advantages compared with traditional technology:
1. Drawing review: It makes up for the limitations of two-dimensional plan drawings, and feels that you can also review drawings in collaboration with multiple professionals and make corrections together.
2. Layout of the construction site: Layout of the tower crane and construction elevator in the three-dimensional vision through BIM technology, intuitively perceive whether the spatial layout is smooth and reasonable. Whether the movement of people and machines is smooth. Reduce the construction cost of temporary roads, save energy, and be green and environmentally friendly.
3. Comprehensive pipeline design optimization: Based on the comprehensive design optimization of BIM pipelines, pipeline installation is faster, more labor-saving, and more intuitive; it minimizes the risk of drawing errors, improves the level of refined management of electromechanical engineering projects, and reduces the number of technicians. Deepen the labor intensity of drawings.
After the laboratory is put into use, the digital laboratory uses operations, process records and factory model databases through advanced visualization, simulation and document management to improve product quality and the quality and dynamic performance involved in the production process. For example, the introduction of digital laboratory in middle school physics experiment teaching and the application of DIS experiment (digital experimental system) have realized the leap from a single instrument to a digital multifunctional integrated system. The digital experiment system is generally composed of three parts: sensors, data collectors and software packages. It can be run on an ordinary personal computer and can display, monitor, record in real time and synchronize the data processing and analysis by the computer. This kind of experimental method is new, such as the human-computer cooperative experiment that allows students to contact sensors and computers, which can broaden their horizons; it can also provide a platform for students who have the ability to learn to do exploratory experiments; it is conducive to the collection of experimental data; it can assist the teaching of physics experiments; affect physics Reform of experimental teaching thinking.