The microscopic world under the lens of digital metallographic microscope
The application fields of digital metallographic microscopes cover almost all industries, such as teaching, scientific research, manufacturing, science and many other fields. Digital metallographic microscopes are found wherever there are applications. They are everywhere. Digital metallographic microscopes can always provide technicians with A pair of "intelligent eyes" can see the microscopic world under the lens.
Due to the particularity and individuality of the use of ordinary microscopes, traditional observation under the microscope makes it difficult for students to receive effective guidance from teachers. With the introduction and application of digital metallographic microscopes and digital interactive classrooms, the traditional method of individual teacher-assisted observation has become more difficult. The teaching method of teaching students to use microscopes to observe microscopic morphology has become an interactive, image-sharing, and efficient teaching system between teachers and students.
Some problems existing in traditional biological experiment teaching mainly include the following points:
1) Lack of communication and interaction between teachers, students and classmates;
2) The existing optical microscope has a single function and limited teaching content;
3) Experimental phenomena and experimental processes cannot be saved;
4) Good experiments cannot be reproduced and shared;
5) The time in one class is limited, the teacher's guidance is individual, and it is impossible to observe the experimental progress and phenomena of the whole class at the same time.
The above problems can be perfectly solved using digital metallographic microscopes or in digital interactive classrooms.
Features of digital metallographic microscope
? Efficient observation, enabling efficient microscopic observation, intuitive magnification operation, and excellent color reproduction
? Various observation methods, bright field, dark field, MIX (bright field + dark field), differential interference, polarized light
? Convenient image acquisition, image acquisition methods include extended depth of field (EFI) and 3D imaging, panoramic image acquisition, dynamic image acquisition and program image acquisition
? Accurate measurement, whether real-time measurement, 2D and 3D measurement, measurement accuracy and repeatability, automatic calibration and reproducibility self-test are guaranteed
? Convenient report sharing
? Rich metallographic analysis software, layer depth length determination, phase area content determination, grain size rating, cast iron metallographic analysis, non-metallic inclusions in steel, particle statistical analysis, non-ferrous metal metallographic analysis
