Method for observing real topography of nonmetallic inclusion in steel

Abstract

The invention discloses a method for observing real topography of nonmetallic inclusion in steel, which belongs to the technical field of steelmaking and continuous casting. The method comprises the following steps: preparing a metallographic model, then mixing several of organic solves such as bromine water, methanol, ethanol, acetone and the like to form buffer solution, adding KCl or NaCl or HCl solution into the buffer solution to form electrolyte, performing surface electrolysis corrosion on the polished metallographic model by using the electrolyte, and controlling the corrosion thickness by controlling electrolysis current and electrolysis time, wherein the nonmetallic inclusion is highlighted on the mirror face of the metallographic model after the corrosion and the real topography of the nonmetallic inclusion with different dimensions is completely represented. The three-dimensional real topography of the nonmetallic inclusion is observed through a metallographic microscope or a scanning electron microscope or a field emission scanning electron microscope. The application and popularization of the method are favorable for deeper comprehension and development of people on the formation, transformation and removal of the nonmetallic inclusion during the steelmaking and continuous casting, and have great guide significance for high-purity steel production.

Description

technical field The invention belongs to the technical field of steelmaking and continuous casting, and in particular provides a method for characterizing the morphology of non-metallic inclusions in steel, which can control the cleanliness of molten steel and various types of non-metallic inclusions in the steelmaking and continuous casting process. It is of great significance to reveal the real morphology existing in molten steel. Background technique Non-metallic inclusions in steel greatly affect the purity of molten steel. As the requirements for steel quality become more and more stringent, how to effectively understand and improve non-metallic inclusions in steel is becoming more and more important. Only by having an accurate understanding of the shape of non-metallic inclusions in steel can they be well controlled and removed during the smelting process. The traditional methods for characterizing inclusions in steel mainly include: (1) Metallographic Microscopic...

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Problems solved by technology

(2) Image scanning method (IA); use a high-speed computer microscope to scan the image, and distinguish light and dark areas according to the intermittent grayscale, which is easy to measure a large area and a large number of inclusions, with a high degree of automation, and can obtain volume fraction and particle size Distribution histogram, quantitative and other information, but it is susceptible to interference such as scratches, pits, pits, dust, etc., which reduces the accuracy of analysis

There are many traditional methods for characterizing non-metallic inclusions, but it is

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