JP2008164410A - Method of inspecting steel material - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a non-destructive inspecting method of a steel material capable of inspecting a crystal state of the stainless steel material easily, in a short time, in a receiving site. <P>SOLUTION: In the method of inspecting the stainless steel material manufactured through a heat treatment process, hydrofluoric acid based pickle is applied to the stainless steel material, and the goodness/badness of the crystal state of the stainless steel material is inspected based on the tarnishing state of the stainless steel material. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a steel material inspection method for inspecting a stainless steel material manufactured through a heat treatment step.

  Stainless steel materials such as austenitic stainless steel materials (SUS304, etc. defined by JIS standards) are manufactured through a heat treatment process.

6 and 7 are diagrams showing a metal structure of a stainless steel material observed with a metal microscope.
When the heat treatment process is appropriately performed for the SUS steel material, the metal structure becomes a solid solution structure as shown in FIG. The solid solution structure is a structure in which Cr (chromium) is uniformly distributed in the metal structure and has high corrosion resistance. Appropriate heat treatment is a process in which the SUS steel material is kept at a temperature of 1050 to 1100 ° C., and then rapidly cooled to solidify carbides and the like in the base material.

On the other hand, when the heat treatment process is insufficient, the metal structure becomes a sensitized structure as shown in FIG. Sensitized tissue is sensitive to corrosion. Insufficient heat treatment is, for example, a process in which SUS steel is heated at about 600 ° C. for 2 hours or more and then slowly cooled. When the SUS steel is exposed to a temperature of about 600 ° C., Cr carbide (Cr ₂₃ C ₆ ) precipitates at the crystal grain boundary, and Cr is collected at the crystal grain boundary. Can do. By forming a Cr-deficient region, the corrosion resistance of the SUS steel material is lowered. In the metal structure of FIG. 7, a line portion (for example, a portion of line L) is a crystal grain boundary. The area around the line L is a Cr-deficient region.

When SUS steel is used for a product, it is necessary to inspect whether the steel satisfies a sufficient quality at the stage of acceptance inspection. Purchasing SUS steel with improper acceptance inspection and insufficient heat treatment process and using it in products can cause serious problems. For example, if SUS steel material with insufficient heat treatment process is used as a component of a pressure transmitter, the pressure transmitter placed at the field site may be corroded, causing an accident of transmitter destruction.
Even if the components of SUS steel are the same, the metal structure may change during the heat treatment process. For this reason, it is necessary to strictly inspect the crystalline state of the metal structure in the acceptance inspection of the steel material.

  When the supplier of the stainless steel material used for the flowmeter is changed, it is unclear what kind of heat treatment process the stainless steel material obtained from the new supplier was manufactured. For this reason, it is necessary for the buyer side to perform an acceptance inspection to check whether sufficient quality is satisfied.

Conventional inspection of stainless steel has the following methods.
(A) The components of the stainless steel material are analyzed with a fluorescent X-ray analyzer.
(B) The metal structure of the stainless steel material is observed using a metal microscope.

Patent Document 1 describes an inspection method for inspecting a weld defect of a fillet weld portion of a steel material with an ultrasonic inspection apparatus.
Patent Document 2 describes a diagnostic method for diagnosing the thermal history of a steel material by causing an eddy current to flow on the surface of the steel material with an electromagnetic ultrasonic sensor.

Japanese Patent Laid-Open No. 10-10094 JP-A-8-278287

However, in the method (a), the components of the steel material can be analyzed, but the state of the metal structure cannot be inspected.
In the method (b), since the structure is observed with a metal microscope, the time required for the inspection becomes longer. Furthermore, it is troublesome to bring the microscope to the reception site for inspection.

  The present invention has been made to solve the above-described problems. A hydrofluoric acid pickling solution is applied to a stainless steel material, and the corrosion resistance (crystalline state) of the stainless steel material is inspected based on the discolored state of the stainless steel material. Accordingly, an object of the present invention is to realize a non-destructive steel material inspection method capable of easily and easily inspecting the crystal state of a stainless steel material in a short time at a reception site.

  In order to solve such a problem, the present invention has the following configuration.

(1) In a steel material inspection method for inspecting a stainless steel material manufactured through a heat treatment step,
A method for inspecting a steel material, comprising applying a hydrofluoric acid pickling solution to a stainless steel material and inspecting the quality of the crystal state of the stainless steel material based on the discolored state of the stainless steel material.

(2) In the steel material inspection method for inspecting the stainless steel material manufactured through the heat treatment step,
A method for inspecting a steel material comprising immersing a stainless steel material in a hydrofluoric acid pickling solution and inspecting the quality of the crystal state of the stainless steel material based on the discolored state of the immersed stainless steel material.

(3) After applying the hydrofluoric acid pickling solution to the stainless steel material, or after immersing the stainless steel material in the hydrofluoric acid pickling solution, if the stainless steel material becomes discolored due to rust, the crystalline state of the stainless steel material changes. The method for inspecting a steel material according to (1) or (2), wherein the steel material is defective.

(4) The method for inspecting a steel material according to any one of (1) to (3), wherein the hydrofluoric acid pickling solution contains hydrofluoric acid and nitric acid as components.

(5) The steel material inspection method according to any one of (1) to (4), wherein the hydrofluoric acid pickling liquid is a passivating acid detergent.

(6) The method for inspecting a steel material according to any one of (1) to (5), wherein the stainless steel material is a stainless steel material containing chromium.

(7) The component of the stainless steel material is analyzed by a portable elemental analyzer, and if the result of the analysis shows that the component of the stainless steel material satisfies the requirements, the crystal state of the stainless steel material is inspected for quality. The steel material inspection method according to any one of claims (1) to (6).

(8) The method for inspecting a steel material according to (2), wherein the hydrofluoric acid pickling solution in which the stainless steel material is immersed is a transparent liquid or a gel material.

As is apparent from the above description, the present invention has the following effects.
(1) Applying a hydrofluoric acid pickling solution to a stainless steel material, and examining the corrosion resistance (crystal state) of the stainless steel material by examining the discolored state of the stainless steel material. For this reason, the crystalline state of the stainless steel material can be easily inspected in a short time at the reception site. Inspection can be done non-destructively. Thereby, it is possible to inspect the crystal quality in the total process from the steel material to the product with respect to the stainless steel material.
(2) Since the hydrofluoric acid pickling solution is a passivating acid detergent, the substrate is not worn even when applied to a stainless steel material.
(3) Since the inspection target is a stainless steel material containing chromium, it is possible to inspect the constituent members of the field device. Thereby, even when the supplier of the stainless steel material used for the flowmeter is changed, the stainless steel material manufactured through an insufficient heat treatment process can be excluded by the acceptance inspection.
(4) By using the inspection of the crystal state and the component analysis in combination, a more sufficient acceptance inspection can be realized.

Hereinafter, the present invention will be described in detail with reference to the drawings.
FIG. 1 is an explanatory view showing an embodiment of the method according to the present invention.

As shown in FIG. 1A, a hydrofluoric acid pickling solution 20 is applied to a stainless steel material 10 to be inspected.
The stainless steel material 10 to be inspected is, for example, a stainless steel material containing chromium. Examples of stainless steel materials containing chromium include martensitic stainless steel materials and austenitic stainless steel materials. As an example, a SUS steel material (for example, SUS304) defined by the JIS standard is applicable.

The hydrofluoric acid pickling liquid 20 is a liquid containing, for example, hydrofluoric acid and nitric acid as components. As an example of the component ratio, hydrofluoric acid is 5 wt% (wt% is wt%), nitric acid is 31 wt%, and the others are 64 wt%.
The present invention is characterized in that a hydrofluoric acid pickling solution that has been used for inspecting a change in crystal structure generated in a welded portion of a stainless steel material is used for quality inspection of the crystal state of the stainless steel material.
Since the hydrofluoric acid pickling solution 20 is a passivating acid detergent, the substrate is not worn even when applied to a stainless steel material.

Application of the hydrofluoric acid pickling solution 20 to the stainless steel material 10 is performed, for example, as follows. The coating apparatus 30 applies the hydrofluoric acid pickling liquid contained in the container 40 to the brush 31 and coats the surface of the stainless steel material 10.
However, the present invention is not limited to this, and it may be applied manually using a brush.
After applying the hydrofluoric acid pickling solution 20 to the stainless steel material 10, it waits for a predetermined time, for example, 1-2 minutes.

After waiting for a predetermined time, as shown in FIG. 1B, when the surface of the stainless steel material 10 is not rusted and discolored, the stainless steel material is determined as a good product. The surface of the stainless steel material in this case is silver white.
The metal structure of such a stainless steel material is a solid solution structure as shown in FIG. In a stainless steel material having a solid solution structure, Cr (chromium) is evenly distributed in the metal structure and has high corrosion resistance. Rust does not occur because of high corrosion resistance.

  After waiting for a predetermined time, as shown in FIG. 1C, when the surface of the stainless steel material 10 has rust 50 and turns brown, the stainless steel material is determined to be defective. The metal structure of such a stainless steel material is a sensitized structure as shown in FIG. In the stainless steel material having a sensitized structure, a Cr-deficient region is formed in the vicinity of the grain boundary, and the corrosion resistance is lowered. For this reason, the stainless steel material is rusted and turns brown.

  Whether the stainless steel material is a good product or a defective product may be determined, for example, by visual observation or by a camera image. When the determination is made based on the camera image, the image captured by the camera is compared with a reference image prepared in advance, and the determination is made based on the comparison result.

FIG. 2 is a flowchart showing the processing procedure of the method according to the present invention.
A description will be given in the order of steps in the flowchart.

(S1) Accept a stainless steel material. The received stainless steel material is inspected according to the following procedure.
(S2) A hydrofluoric acid pickling solution is applied to the stainless steel material.
(S3) Wait for a predetermined time, for example, 1-2 minutes.

(S4) When a predetermined time has elapsed, it is determined whether or not rust has occurred in the stainless steel material.
(S5) When rust is generated in the stainless steel material, the stainless steel material is determined to be defective. Since the metal structure of the defective stainless steel material is a sensitized structure and has low corrosion resistance, rust is generated on the surface of the steel material and turns brown. It can be easily identified by visual inspection by turning brown.
(S6) When rust is not generated in the stainless steel material, the stainless steel material is determined as a non-defective product. The metal structure of a good stainless steel material is a solid solution structure, has high corrosion resistance, and rust does not occur on the surface of the steel material. In this case, the steel material surface is silver white.
(S7) Wash the non-defective stainless steel material with water. By washing with water, a passive film is formed on the surface of the steel material, and the steel material is less likely to rust.

Since it is the inspection of the procedure described above, it can be easily performed in a short time at the reception site of the stainless steel material.
Even with SUS steel of the same component, the metal structure may change in the heat treatment process depending on the steel. Therefore, the crystal structure of the metal structure is inspected at the reception site of the stainless steel material by the method of the present invention shown in FIGS. Thereby, a defective stainless steel material having an insufficient heat treatment process can be easily identified at the reception site. Inspection can be performed non-destructively on stainless steel.

In the embodiment, the hydrofluoric acid pickling solution is applied to the stainless steel material with a brush. However, the invention is not limited to this, and the hydrofluoric acid pickling solution may be applied to the stainless steel material with a spray-type spraying device.
Further, as shown in FIG. 3, the stainless steel material 10 may be immersed in a container 60 containing the hydrofluoric acid pickling solution 20. In this case, the hydrofluoric acid pickling solution 20 is a transparent liquid or a transparent or translucent gel substance so that the discolored state of the stainless steel material 10 can be seen.

FIG. 4 is a flowchart showing a procedure for inspecting a stainless steel material performed at the reception site.
A description will be given in the order of steps in the flowchart.

(S1) Obtain a stainless steel material. The obtained stainless steel material is inspected according to the following procedure.
(S2) The components of the stainless steel material are analyzed. The component analysis is performed by applying X-rays to the stainless steel material 10 with a portable elemental analyzer, for example, a portable fluorescent X-ray analyzer 70 as shown in FIG. The portable fluorescent X-ray analyzer 70 irradiates the planar region M with X-rays and performs component analysis on this region. Portable fluorescent X-ray analyzers are commercially available. Since a portable X-ray fluorescence analyzer is used, analysis can be easily performed at the reception site.
As a result of analyzing the components, if the ratio of the components contained in the stainless steel material satisfies the requirements stipulated in the standard, the analysis result is “good”. For example, in the case of stainless steel material SUS304 specified by JIS standard, analysis is performed when the ratio of Cr (chromium) contained in the component is 18% ± allowable and the ratio of Ni (nickel) is 8% ± allowable. The result is “good”.

(S3) If the component ratio contained in the stainless steel material does not satisfy the requirements defined in the standard, the analysis result is set to “defective”.
(S4) If the analysis result of the component is “good”, a corrosion inspection of the stainless steel material is performed. This inspection is the inspection shown in FIGS. This is a test for applying a hydrofluoric acid pickling solution to a stainless steel material and judging the quality of the crystalline state based on the corrosion state of the stainless steel material.
If the result of the corrosion test is “defective”, the process goes to step S3.

(S5) If the result of the corrosion inspection is “good”, the magnetic inspection of the stainless steel material is performed. In this inspection, a magnet or a coil that generates magnetic field lines is applied to a stainless steel material, and at this time, an inspection is performed based on whether the stainless steel material is adsorbed by the magnet or the coil. Austenitic stainless steel materials are not attracted to magnets and coils in the case of non-defective products. In the case of a good product, martensitic stainless steel is adsorbed by a magnet or a coil.
Since a good austenitic stainless steel material may be magnetized by a magnet or a coil, a demagnetization treatment is performed as necessary after the magnetic inspection.
If the result of the magnetic inspection is “defective”, the process goes to step S3.
(S6) When the result of the magnetic inspection is “good”, the stainless steel material is determined as a good product.

In this way, component analysis, corrosion inspection, and magnetic inspection can be easily performed at the reception site.
The magnetic inspection need not be performed at the reception site.
When it is unclear whether the product is good or defective in the inspection of FIG. 4, the steel structure may be observed using a metal microscope at a location different from the reception site.

It is explanatory drawing which shows one Example of the method concerning this invention. It is the flowchart which showed the process sequence of the method concerning this invention. It is explanatory drawing which shows the other Example of the method concerning this invention. It is the flowchart which showed the test | inspection procedure of the stainless steel material performed in a receiving field. It is explanatory drawing which shows the method of a component analysis of stainless steel material. It is the figure which showed the metal structure of the stainless steel material observed with the metal microscope. It is the figure which showed the metal structure of the stainless steel material observed with the metal microscope.

Explanation of symbols

10 Stainless steel material 20 Hydrofluoric acid pickling solution 50 Rust 70 Portable X-ray fluorescence analyzer

Claims (8)

In the steel material inspection method for inspecting the stainless steel material manufactured through the heat treatment process,
A method for inspecting a steel material, comprising applying a hydrofluoric acid pickling solution to a stainless steel material and inspecting the quality of the crystal state of the stainless steel material based on the discolored state of the stainless steel material. In the steel material inspection method for inspecting the stainless steel material manufactured through the heat treatment process,
A method for inspecting a steel material comprising immersing a stainless steel material in a hydrofluoric acid pickling solution and inspecting the quality of the crystal state of the stainless steel material based on the discolored state of the immersed stainless steel material.   After applying the hydrofluoric acid pickling solution to the stainless steel material, or after immersing the stainless steel material in the hydrofluoric acid pickling solution, if the stainless steel material becomes discolored due to rust, the crystalline state of the stainless steel material becomes defective. The method for inspecting a steel material according to claim 1 or 2.   The steel material inspection method according to any one of claims 1 to 3, wherein the hydrofluoric acid pickling solution contains hydrofluoric acid and nitric acid as components.   5. The method for inspecting a steel material according to claim 1, wherein the hydrofluoric acid pickling liquid is a passivating acid detergent.   6. The method for inspecting a steel material according to claim 1, wherein the stainless steel material is a stainless steel material containing chromium.   The component of the stainless steel material is analyzed by a portable elemental analyzer, and if the component of the stainless steel material satisfies the requirements as a result of the analysis, the quality of the crystal state of the stainless steel material is inspected. The inspection method of the steel materials in any one of thru | or 6.   3. The method for inspecting a steel material according to claim 2, wherein the hydrofluoric acid pickling liquid in which the stainless steel material is immersed is a transparent liquid or a gel substance.

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