Metallurgical microscope

Metallurgical microscope is the optical microscope, photoelectric conversion technology, computer image processing technology which combines high-tech products developed into, the computer can be easily observed metallographic images to map the analysis of metallographic , ratings, etc. as well as the picture output and printing.

As alloy composition, heat treatment, hot and cold processing of metal materials directly affect the internal organization, structure changes, so that the mechanical properties of mechanical changes. Therefore, examination by optical microscope to observe the internal structure of metals is an important industrial production means. Mainly by the optical microscope optical system, lighting, mechanical systems, accessories devices (including photographic or other devices such as hardness) composition. According to the metal surface of the sample material from different organizations of light reflection characteristics, with a microscope in the visible range for these organizations to conduct optical materials research and qualitative and quantitative description. It can display 500 to 0.2m-scale features of the metal structure. As early as 1841, the Russians magnifying glass to study in Damascus steel sword on the pattern. To 1863, the British petrographic methods, including sample preparation, polishing, and are insensitive to such technology to the steel research and development of metallurgical technology, and was later sold for a number of low magnification Metallographic photographs and other organizations. Antonie Philips van Leeuwenhoek (1632-1723), a Dutch tradesman and scientist should be credited for the basic invention of this instrument.To the early 20th century, optical metallographic microscopy is improving daily, and generally promote the use of metals and alloys in micro-analysis, is still by far the field of metal in a basic techniques.

A metallurgical microscope uses a different lighting method than a conventional microscope and can illuminate solid specimens to identify, inspect, and measure them. They are like otheroptical microscopes with the exception of the lighting orientation. Some industries use inverted metallurgical microscopes, which observe the specimen from below the stage or table. Electronic parts manufacturers, forensic laboratories, and metal foundries all use this type of instrument. A conventional microscope illuminates a transparent specimen from below the stage, making it visible through the eyepiece. Since light cannot penetrate opaque or solid objects, this is not a suitable method for observing these samples under magnification. Metallurgical microscopes illuminate objects from above, either with an external light source or with that light travels through the magnification objectives using beam splitters. This lighting technique illuminates the entire object without creating distracting or unnecessary reflections. The illumination technology may include color filters or filters designed to change polarization and light intensity. These options allow viewing objects in bright or dark field applications. The filters may be contained in a removable cartridge within the microscope body.Metallurgical microscopes are used for metallurgical inspection including metals, ceramics and other materials.  A microscope is an instrument capable of producing a magnified image of a small object.  The most common configurations of metallurgical microscopes are student, benchtop and research.  Student microscopes are

the smallest and least expensive type of microscope. They are capable of advanced techniques and documentation even though they are for student use. Benchtop microscopes are used in various industries like textiles and animal husbandry.  Benchtop microscopes can do many techniques but are limited by the amount of techniques they can be used for at one time.  Research microscopes are large, weighing in the range of 30Kg to 50 Kg. This mass is composed of complex optical, mechanical, and electronic systems. They may use multiple cameras, large specimens, and the widest range of simultaneous techniques.

Metallurgical microscopes can be one of many types of technologies.  The most common metallurgical microscopes are acoustic or ultrasonic microscopes which can be used to examine delimitations, cracks and other anomalies nondestructively and inverted microscopes which are useful for flat polished metallurgical, ceramic, or optical samples.  Other technologies include microwave microscopes, compound microscopes, fluorescent microscopes, laser or confocal microscopes, polarizing microscopes, portable field microscopes, scanning electron (SEM) microscopes, scanning probe or atomic force microscopes (SPM / AFM), stereoscopes and transmission electron microscopes (TEM).

Important parameters in specifying metallurgical microscopes include total magnification and resolution.  Total magnification is a ratio of the size of an image to its corresponding object. This is usually determined by linear measurement.  Resolution is the fineness of detail in an object that is revealed by an optical device. Objectively, resolution is specified as the minimum distance between two lines or points in the object that are perceived as separate by the human eye. Subjectively, the images of the two resolved points must fall on two receptors (rods or cones), which are separated by at least one other receptor on the retina of the eye.Metallurgical microscopes can come in one of many types of eyepiece styles.  These include monocular, binocular, trinocular or dual head.  A monocular eyepiece has one objective and one body tube for monocular vision.  Binocular microscopes are fitted with double eyepieces for vision with both eyes. The purpose in dividing the same image from a single objective of the usual compound microscope is to reduce eyestrain and muscular fatigue, which may result from monocular, high-power microscopy.  These types of microscopes are also used for stereoscopic vision, which allows for depth perception of the sample.  Trinocular microscopes are fitted with a vertical tube at the top and regular binocular eyepieces at 30 degrees.  The vertical tube is often used for a digital camera or a second observer.  A dual head has one vertical eyepiece lens and a second eyepiece off the side at 45 degrees (So that two people can view the sample at one time, or one person and a camera.   Important features in specifying metallurgical microscopes include a digital display, mechanical stages, fine focus, computer interfaces, and image analysis processing software.