KR102128656B1 - Metal analysis method and metal analysis device for stainless steel - Google Patents

Abstract

The present invention relates to a stainless-only metal component analysis method and a stainless-specific metal component analysis device capable of accurately and reliably analyzing stainless steel types through multiple analysis processes targeting stainless steel among non-ferrous metals. According to the present invention, the effective distance measurement step of calculating and notifying the analysis effective distance for the stainless metal to be analyzed; A corrosion treatment step of corrosion of the stainless metal by spraying an oxide material that will corrode the stainless metal to be analyzed at the announced effective distance; A metal grasping step of deriving an analysis factor from the corroded stainless metal; A steel type analysis step of analyzing a stainless steel type based on at least one of a crystal structure and a corrosion degree for the corroded metal; And a data storage/display step of storing and displaying the stainless steel type analyzed in the steel type analysis step.

Description

Metal component analysis method for exclusive use of stainless steel and metal component analysis device for exclusive use of stainless steel {METAL ANALYSIS METHOD AND METAL ANALYSIS DEVICE FOR STAINLESS STEEL}

The present invention relates to a method for analyzing a metal component for exclusive use of stainless steel and an apparatus for analyzing a metal component for exclusive use of stainless steel, and more specifically, a metal for exclusive use of stainless steel that can accurately and reliably analyze stainless steel types through multiple analysis processes targeting stainless steel among non-ferrous metals. It relates to a component analysis method and a metal component analysis device for exclusive use of stainless steel.

In general, the X-ray device is bulky and easy to be exposed to radiation, so it has been limited to places used for medical purposes, such as in a hospital. Furthermore, it has been used to analyze metal content as it is developed as a device for analyzing metal.

Examples of metals include nickel, iron, copper, aluminum, gold, tin, and uranium. Among the most common metals used in industry, iron (S400, PO, CR), etc., and non-ferrous metals include stainless steel (316, 304, 430). It is very important to use materials separately in each industry. If a customer requests a material with the exact specifications, but the manufacturer manufactures a material of a different steel type, this may cause serious defects that must be disposed of.

In addition, in the case of the conventional metal analyzer, foreign products that identify the components of all metals, such as iron and non-ferrous metals, are very expensive (about 30 million to 40 million won), so it is not necessary to analyze only specific metals depending on the user. There was a problem of having to purchase an expensive analyzer.

In addition, in the case of the conventional metal analyzer, since the component is analyzed using only an X-ray and a proximity sensor, there is a problem in that accuracy is relatively low in analyzing a specific metal component.

(Document 1) Republic of Korea Registered Patent Publication 10-0899011 (2009.05.21. (Document 2) Republic of Korea Patent Publication No. 10-2001-0088425 (2001.09.26. published) (Document 3) Republic of Korea Patent Publication 10-2003-0041724 (2003.05.27. published) (Document 4) Republic of Korea Registered Patent Publication 10-0130943 (November 25, 1997 registration)

Therefore, the present invention for solving the above-described conventional problems, stainless steel-specific metal component analysis method and stainless-specific metal component analysis capable of accurately and reliably analyzing stainless steel types through multiple analysis processes targeting stainless steel among non-ferrous metals The purpose is to provide a device.

In addition, the present invention can provide a metal component analyzer for exclusive use of stainless steel, and thus provides a significantly cheaper device than the existing analyzer. There is this.

The problem of the present invention is not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention for achieving the objects and other features of the present invention, the effective distance measurement step of calculating and notifying the analysis effective distance for the stainless metal to be analyzed; A corrosion treatment step of corrosion of the stainless metal by spraying an oxide material that will corrode the stainless metal to be analyzed at the announced effective distance; A metal grasping step of deriving an analysis factor from the corroded stainless metal; A steel type analysis step of analyzing a stainless steel type based on at least one of a crystal structure and a corrosion degree for the corroded metal; And a data storage/display step of storing and displaying the stainless steel type analyzed in the steel type analysis step.

In one aspect of the present invention, the effective distance measurement step detects a distance through a reflection type proximity sensor provided in the muzzle of an analysis device having a gun type appearance, and the detected distance is applied to the analysis device. When a preset effective distance stored is reached, notification is made by at least one of audible notification and visual notification, and the corrosion treatment step is performed by spraying an oxide material that can corrode stainless metal to analyze the stainless metal to be analyzed. This corrosion is performed, and the metal grasping step consists of irradiating X-rays with a corrosion site of stainless metal, and the steel type analysis step is a crystal structure and corrosion degree obtained through diffraction of the irradiated X-rays as an analysis factor. It is made to determine the steel type based on at least one of the, the data storage / display step may be made to store the data for the determined steel type, and display the determined steel type of the metal.

In one aspect of the present invention, the stainless metal to be analyzed through the image-taking means configured in the gun-type analysis device, the captured image data is further included to be stored and displayed together with the data for the determined steel type. can do.

In one aspect of the present invention, it is preferable to further include a backup step of backing up the stainless steel type analyzed in the steel type analysis step to an external device through a communication connection port or a wireless communication module configured in the gun type analysis device. .

In one aspect of the present invention, the steel type analysis step may include determining the stainless steel type based on magnetic properties of the stainless metal to be analyzed.

According to another aspect of the present invention, a metal component analysis device for analyzing steel types of stainless metal, comprising: a gun-type device body having a handle; A distance measurement sensor configured at an end side of the device body to measure an effective distance to a stainless metal to be analyzed; An oxidizing spraying means which is configured on an end side of the device body and sprays an oxidizing material to corrode the stainless metal to be analyzed; X-ray irradiation means is configured on the end side of the device body for irradiating X-rays; A central processing unit including an analysis unit for analyzing and deriving steel type analysis factors through X-rays irradiated from the X-ray irradiation means, and a control unit for controlling the operation of the distance measurement sensor, the oxide injection means, and the X-ray irradiation means; A storage medium for storing result data analyzed by the analysis unit of the central processing unit; A display unit configured on one side of the device body to display result data; A power supply unit for supplying power to components that need power supply among the components; And an on/off control of the entire device and an operation control unit for setting or selecting the operation of each component.

In another aspect of the present invention, an image acquisition camera configured to photograph a stainless metal to be analyzed and configured at an end side of the device body; The device may further include a shielding film or a shielding housing configured to shield the oxide material sprayed by the oxidizing spray means and X-rays irradiated by the X-ray irradiation means from the outside.

In another aspect of the present invention, a magnetic metal sensor configured on an end side of the device body to detect magnetic properties of the stainless metal to be analyzed; And a communication connection port or a wireless communication module configured to be configured in the device body to back up the analyzed data to an external device wired or wirelessly, wherein the steel type analysis factor is the magnetic metal sensor for the stainless metal to be analyzed. It may include at least one of the magnetic properties detected by, and the crystal structure and corrosion degree for the stainless metal portion sprayed by the oxide spraying means.

According to the method for analyzing a metal component for exclusive use of stainless steel and an analysis apparatus for metal component for exclusive use of stainless steel according to the present invention, stainless steel types, for example, in the entire industrial area, have the greatest demand in a multi-analysis process targeting stainless steel among non-ferrous metals. It has the effect of accurately and reliably analyzing SUS316, SUS304, SUS400, and SUS200.

In addition, according to the present invention, it is possible to provide a metal component analyzer for exclusive use of stainless steel, thereby providing a remarkably cheaper device than the existing analyzer, thereby promoting price competitiveness, and securing an excellent marketability throughout the industry.

The effects of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a flow chart showing a method for analyzing a metal component for exclusive use of stainless steel according to the present invention.
2 is a block diagram showing the configuration of a metal component analysis device for exclusive use of stainless steel according to the present invention.

Additional objects, features and advantages of the invention may be more clearly understood from the following detailed description and accompanying drawings.

Prior to the detailed description of the present invention, the present invention is capable of various changes, and may have various embodiments. The examples described below and illustrated in the drawings are intended to limit the present invention to specific embodiments. No, it should be understood to include all modifications, equivalents, or substitutes included in the spirit and scope of the present invention.

When an element is said to be "connected" or "connected" to another component, it is understood that other components may be directly connected or connected to the other component, but other components may exist in the middle. It should be. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that no other component exists in the middle.

The terms used in this specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this specification, terms such as “include” or “have” are intended to indicate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, and that one or more other features are present. It should be understood that the existence or addition possibilities of fields or numbers, steps, operations, components, parts or combinations thereof are not excluded in advance.

In addition, terms such as "... unit", "... unit", "... module" described in the specification mean a unit that processes at least one function or operation, which is hardware or software or hardware and It can be implemented with a combination of software.

In addition, in the description with reference to the accompanying drawings, the same reference numerals are assigned to the same components regardless of reference numerals, and redundant descriptions thereof will be omitted. In the description of the present invention, when it is determined that a detailed description of related known technologies may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted.

Hereinafter, a method for analyzing metal components for exclusive use of stainless steel and an apparatus for analyzing metal components for exclusive use of stainless steel according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

First, a method for analyzing a metal component for exclusive use of stainless steel according to the present invention will be described in detail with reference to FIG. 1. 1 is a flow chart showing a method for analyzing a metal component for exclusive use of stainless steel according to the present invention.

The method for analyzing a metal component for exclusive use of stainless steel according to the present invention includes: an effective distance measuring step of calculating and notifying an analysis effective distance for a stainless metal to be analyzed (S100); Corrosion treatment step (S200) to corrode the stainless metal by firing an oxide material that will corrode the stainless metal to be analyzed at the effective distance measured and notified in the effective distance measurement step (S100); A metal grasping step (S300) for deriving an analysis factor from the stainless metal corroded in the corrosion treatment step (S200); A steel type analysis step (S400) of analyzing stainless steel types based on the crystal structure and/or corrosion degree of the metals identified in the metal identification step (S300); And a data storage/display step (S500) of storing and displaying the stainless steel type analyzed in the steel type analysis step (S400).

In the effective distance measurement step 100, for example, a distance is detected by a reflection type proximity sensor provided in the muzzle of an analysis device having a gun type appearance, and the detected distance is stored in the analysis device When a preset effective distance is reached, an audible notification (for example, a buzzer) and/or a visual notification (for example, an LED display, etc.) may be used for notification.

Next, in the corrosion treatment step (S200), a certain amount of an oxidizing material (eg, sulfuric acid) capable of corroding stainless metal is provided so that the stainless metal to be analyzed is corroded.

For example, in the corrosion treatment step (S200), the oxide material stored in the analysis device is fired from one side of the muzzle of the analysis device by operating an operation button or an operation trigger configured in the analysis device having a gun-type appearance. It can be done.

At this time, when the oxide material is fired from the gun-type analysis device, it is preferable that the analysis device has a shielding film or a shielding housing to prevent the oxide material from splashing outward. The shielding film or the shielding housing is shielded to the outside even during X-ray irradiation, which will be described later.

Subsequently, the metal grasping step (S300) uses X-ray diffraction by irradiating X-rays (X-rays) to the corrosion site of the stainless metal by the corrosion treatment of the corrosion treatment step (S200). The crystal structure and/or corrosion degree of stainless metal will be grasped.

For example, the metal grasping step S300 may be performed by allowing X-rays to be irradiated from X-rays irradiating means configured on the other side of the muzzle of the analyzer having a gun-type appearance.

Next, the steel grade analysis step (S400) determines the steel grade by comparing and determining the crystal structure of the previously stored steel grade based on the crystal structure of the metal identified in the metal grasping step (S300).

In addition, the steel type analysis step (S400) is performed by determining the steel type through a comparison determination with the crystal structure of the steel type pre-stored first, or separately, by comparing the determined corrosion degree of the metal and the corrosion degree of the previously stored steel type. It may include having to decide.

In the steel type analysis step S400, the steel type can be identified through the crystal structure or the corrosion degree of the identified metal, and in addition, the steel type can be more accurately determined by comparing and determining both the crystal structure and the corrosion degree.

Subsequently, in the storage step (S500), the data for the steel type determined by being analyzed in the steel type analysis step (S400) is stored in an internal memory provided in the analysis device, and the steel type determined by the display unit configured on one side of the analysis device is determined. It is made to display.

Here, the method for analyzing the metal component for exclusive use of stainless steel of the present invention captures the stainless metal to be analyzed through an image taking means configured in the gun-type analysis device before the effective distance measurement step (S100) or with the effective distance measurement step (S100). The photographed image data may further include storing and displaying the steel grades of the metal determined in the storage step (S500).

In addition, the analysis method of the present invention may be made to provide an image of a corroded part through the image photographing means by option manipulation or automatic selection.

On the other hand, the method for analyzing metal components for exclusive use of stainless steel of the present invention is connected to an external device (for example, a personal computer, etc.) through a communication connection port configured in a gun type analysis device to store data stored in the storage step (S500). It may further include a backup step (S600) to enable the backup.

Here, the backup step (S600) may be made to backup the stored data by wirelessly connecting to an external terminal device through short-range communication such as Bluetooth.

In addition, in the method for analyzing a metal component for exclusive use of stainless steel of the present invention, the steel type analysis step (S400) may further include a magnetic-based steel type determination step (S410) for auxiliaryly determining the stainless steel type by detecting magnetic properties of the stainless metal to be analyzed. have.

The magnetic-based steel type determination step (S410) detects magnetic properties through a magnetic metal sensor configured in a gun-type analysis device and compares the magnetic properties (magnetic properties for each stainless steel type) with stainless steels having the corresponding magnetic properties. It is made to decide.

In the magnetic-based steel grade determination step (S410 ), the steel grade analysis step (S400) may be omitted and independently performed.

In the above-described method for analyzing metal components exclusively for stainless steel, a process in which a predetermined algorithm such as metal identification and steel type analysis is required is performed by a central processing unit (CPU) provided in the analysis device, which can employ a known software algorithm. Therefore, detailed description thereof will be omitted.

Next, the apparatus for analyzing a metal component for exclusive use of stainless steel according to the present invention will be described in detail with reference to FIG. 2. 2 is a block diagram showing the configuration of a metal component analysis device for exclusive use of stainless steel according to the present invention.

As shown in FIG. 2, the apparatus for analyzing metal components for exclusive use of stainless steel according to the present invention is a metal component analysis apparatus for analyzing steel types of stainless metal, and a gun type apparatus body having a handle portion 101 ( 100); A distance measurement sensor 110 configured to measure an effective distance to a stainless metal to be analyzed by being configured at one end of the device body 100 (muzzle portion 102); An oxidizing agent spraying means 120 configured to be disposed on the other side of the muzzle part 102 of the device body 100 to oxidize the stainless metal to be analyzed; X-ray irradiation means 130 is configured on the other side of the muzzle portion 102 of the device body 100 for irradiating X-rays; An analysis unit for analyzing and deriving steel type analysis factors through X-rays irradiated from the X-ray irradiation means 130, and the distance measuring sensor 110 and the oxide-based injection means 120 and the X-ray irradiation means 130 Central processing unit (CPU) 140 including a control unit for controlling the operation; A storage medium 150 for storing the result data analyzed by the analysis unit of the central processing unit 140; A display unit 160 configured on one side of the device body 100 to display result data; A power supply unit 170 for supplying power to components that need power supply among the components; And an on/off control of the entire device and an operation control unit 180 for setting or selecting the operation of each component.

The device body 100 is provided with a handle portion 101 so that the user can easily grip it, and the muzzle portion 102 is a component for performing an operation required for analysis against the stainless metal to be analyzed (For example, the distance measuring sensor 110, the nozzle sphere of the oxide-based injection means 120, the X-ray irradiation means 130, an image acquisition camera (described later)) may be configured.

The distance measuring sensor 110 may employ a known reflective proximity sensor. The distance measuring sensor 110 detects the distance to the stainless metal to be analyzed, and the central processing unit 140 receiving the detection signal determines whether the specified distance is reached, and when the effective distance is reached, the display unit 160 It may be made to display as a visual notification (for example, a stepwise display) through or audible notification through a buzzer (not shown) configured in the device body 100.

Next, the oxide spraying means 120 is an oxide receptor 121 provided on one side of the inside of the device body 100, a nozzle opening 122 formed on the muzzle portion 102 of the device body 100 And a firing driving means (not shown) for driving the oxide material to be fired through the nozzle hole 122 from the oxide material receptor 121 by manipulation of the trigger 103 configured in the device body 100.

The device body 100 provided with the oxide-based receptor 121 of the oxide-based injection means 120 is opened and closed with a stopper so that the oxide-based receptor 121 can be filled with oxide material (eg, sulfuric acid). Is formed.

The launch driving means (not shown) of the oxide injection means 120 is not particularly limited as long as it is a configuration capable of spraying the oxide contained in the oxide receptor 121 through the nozzle opening 122. Known ones such as a driving method (cylinder driving method) or an electronic driving method (solenoid driving method) can be employed.

Here, the present invention is a shielding film or shield formed on the muzzle portion 102 side of the device body 100 to prevent the oxide material from splashing outward when the oxide material is fired by the oxide material injection means 120 A housing (not shown) may be further included.

The shielding film or the shielding housing allows the X-rays irradiated by the X-ray irradiation means 130 to be described later to be shielded.

Further, the shielding film or the shielding housing may be configured to be slidably movable on the outer surface of the device body 100. Therefore, when the metal component analysis device according to the present invention is not carried or used, the volume can be reduced by moving the shielding film or the shielding housing toward the device body 100 side.

Next, the X-ray irradiation means 130 is not particularly limited as long as it is a configuration capable of irradiating X-rays, and a known one can be employed.

Subsequently, the central processing unit 140 diffracts the X-rays (X-rays) irradiated by the X-ray irradiation means 130 with respect to the portions corroded by the oxide injection means 120. The crystal structure of the stainless metal is extracted through the analysis unit using, and the extracted crystal structure is compared with the crystal structure of the steel type stored in the storage medium 150 to determine the steel type.

In addition, the analysis unit of the central processing unit 140 extracts the corrosion degree of the corrosion site using the diffraction phenomenon of X-rays, and compares the extracted corrosion degree with the corrosion degree stored in the storage medium 150 to determine the steel type. .

Here, in the analysis unit of the central processing unit 140, the steel type crystal according to the crystal structure and the steel type crystal according to the corrosion degree may be made simultaneously or separately, or only one may be performed.

The steel grade results determined and analyzed in this way are stored in the storage medium 150 and the steel grade of the metal determined through the display unit 160 is displayed.

Here, the metal component analysis device according to the present invention, before the effective distance measurement through the distance measurement sensor or with the effective distance measurement, the muzzle portion 102 side of the device body 100 to photograph the object to be analyzed (stainless metal) (For example, the upper portion of the muzzle portion 102) may further include an image acquisition camera 190.

The image acquisition camera 190 may store the image of the photographed analyte in the storage medium 150 together with the steel type analyzed result. Here, the image acquisition camera 190 may also provide an image of the corrosion site.

Next, the power unit 170 is made of a rechargeable battery connected to the power port, it can be made to be charged through the power cable. Of course, the power supply unit 170 may be formed of a replaceable battery, and a rechargeable battery and a replaceable battery may be configured together.

Subsequently, the operation control unit 180 includes an on-off operation unit for turning on/off the power of the entire device, a mode selection operation unit for selecting an operation required for analysis, and a function (for example, battery level display, storage data) It can be made, including a function selection operation unit, etc. that can be selected to load, delete data, etc.).

The operation control unit 180 may be made of a touch input screen capable of manipulating touch input, or may be made of an input button selectable by physical contact.

On the other hand, the metal component analysis device for exclusive use of stainless steel of the present invention is configured on one side of the device body 101 and connected to an external device (for example, a personal computer, etc.) to store and back up data stored in the storage medium 150. It may further include a communication connection port 104 to be connected.

In addition, the metal component analysis device of the present invention may further include a communication module (not shown) that is wirelessly connected to an external terminal device through short-range communication such as Bluetooth to transmit data stored in the storage medium 150 wirelessly. have.

On the other hand, the apparatus for analyzing a metal component for exclusive use of stainless steel of the present invention may further include a magnetic metal sensor (not shown) configured on the muzzle part 103 side of the device body 100 to detect magnetic properties of the stainless metal to be analyzed. have.

The magnetic metal sensor detects the magnetic properties of the stainless metal to be analyzed, and compares the magnetic properties of the stainless steel types stored in the storage medium 150 through the analysis unit of the central control device 140 to stainless steels of the steel type having the corresponding magnetic properties. It can be made to decide.

These magnetic-based steel grade crystals may be made independently or together with the above-described crystal structure determination and/or corrosion degree determination.

According to the method for analyzing metal components for exclusive use of stainless steel and the apparatus for analyzing metal components for exclusive use of stainless steel according to the present invention as described above, stainless steel types, for example, are generally used in all industrial areas through multiple analysis processes targeting stainless steel among non-ferrous metals. It can accurately and reliably analyze SUS316, SUS304, SUS400, SUS200, etc., which have the most demand, and furthermore, it can provide a metal component analysis device for exclusive use of stainless steel. It has the advantage of being able to promote and securing excellent marketability throughout the industry.

The embodiments described in the present specification and the accompanying drawings are merely illustrative of some of the technical spirit included in the present invention. Therefore, the embodiments disclosed in the present specification are not intended to limit the technical spirit of the present invention, but to explain the present invention, it is obvious that the scope of the technical spirit of the present invention is not limited by these embodiments. Within the scope of the technical spirit included in the specification and drawings of the present invention, modifications and specific embodiments that can be easily inferred by those skilled in the art should be interpreted as being included in the scope of the present invention.

S100: effective distance measurement step
S200: Corrosion treatment step
S300: metal grasping step
S400: Steel grade analysis step
S410: Magnetic-based steel grade determination step
S500: Data storage/display phase
S600: backup phase
100: device body
101: handle
102: muzzle
103: trigger
104: communication connection port
110: distance measuring sensor
120: oxide injection means
121: oxide receptor
122: nozzle unit
130: X-ray irradiation means
140: central processing unit
150: storage medium
160: display unit
170: power supply
180: operation control unit
190: Image acquisition camera

Claims (7)

delete delete delete delete delete As a metal component analysis device for analyzing the steel type of stainless metal,
A gun type device body having a handle portion;
A distance measurement sensor configured at an end side of the device body to measure an effective distance to a stainless metal to be analyzed;
An oxidizing spraying means which is configured on an end side of the device body and sprays an oxidizing material to corrode the stainless metal to be analyzed;
X-ray irradiation means is configured on the end side of the device body for irradiating X-rays;
A central processing unit including an analysis unit for analyzing and deriving steel type analysis factors through X-rays irradiated from the X-ray irradiation means, and a control unit for controlling the operation of the distance measurement sensor, the oxide injection means, and the X-ray irradiation means;
A storage medium for storing result data analyzed by the analysis unit of the central processing unit;
A display unit configured on one side of the device body to display result data;
A power supply unit for supplying power to components that need power supply among the components;
An operation control unit for setting/selecting on/off control of the entire device and operation of each component;
An image acquisition camera configured on the end side of the device body to photograph the stainless metal to be analyzed; And
A shielding film or a shielding housing configured on an end side of the device body to shield the oxide material sprayed by the oxide spraying means and the X-ray emitted by the X-ray irradiation means from outside;
A magnetic metal sensor configured at an end side of the device body to detect magnetic properties of the stainless metal to be analyzed; And
Includes a communication connection port or a wireless communication module configured to be configured in the device body to back up the analyzed result data to an external device wired or wirelessly,
The steel type analysis factor includes magnetic properties detected by the magnetic metal sensor with respect to the stainless metal to be analyzed, crystal structure and corrosion degree of the stainless metal part sprayed by the oxide spraying means,
The central processing unit,
When the distance detected through the distance measurement sensor reaches a preset effective distance, it is made to notify by at least one of audible and visual notifications,
A crystal structure of stainless metal is extracted by using a diffraction phenomenon of X-rays irradiated by the X-ray irradiator to a site corroded by the oxide injection means, and the extracted crystal structure is stored in a storage medium. Determine the steel type by judging the crystal structure of the steel type
Using the diffraction phenomenon of the X-rays, the corrosion degree of the corrosion site is extracted, and the extracted corrosion degree is compared with the corrosion degree stored in the storage medium to determine the steel type,
Compared with the magnetic properties detected by the magnetic metal sensor and the magnetic properties of each stainless steel stored in the storage medium, it is determined as stainless steel having the corresponding magnetic properties,
The image data of the stainless metal photographed through the image acquisition camera is stored together with the data for the determined steel type, and is displayed on the display unit.
Metal component analysis device for stainless steel. delete

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