X-ray fluorescent spectrum fundamental parameter method utilizing virtually synthesized standard sample

A basic parameter, fluorescence spectrum technology, applied in the field of X-ray fluorescence spectrum detection, to achieve the effect of solving different problems of different cross-section components and fast analysis speed

Inactive Publication Date: 2014-10-22
DALIAN UNIV OF TECH +4
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  • Abstract
  • Description
  • Claims
  • Application Information

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Problems solved by technology

[0004] The invention solves the problem that X-ray fluorescence spectrum detection of certain material components must rely on a set of standard samples of the same material, classifies metal materials according to substrates, and proposes a de

Method used

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  • X-ray fluorescent spectrum fundamental parameter method utilizing virtually synthesized standard sample

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Effect test

Embodiment 1

[0026] Application of Iron-Based Alloys

[0027] Step 1: This embodiment selects the following standard samples:

[0028] (1) 1Cr18Ni9Ti, 7 pieces, this sleeve is used as the main sleeve, except for the base, it contains: tin, molybdenum, lead, arsenic, tungsten, copper, nickel, cobalt, manganese, arsenic, titanium, phosphorus, silicon, aluminum There are 15 elements in total.

[0029] (2) Austenitic stainless steel ST21-28 series, 8 pieces, adding elements niobium and tantalum.

[0030] (3) Nickel-chromium-molybdenum-copper stainless steel, 5 pieces, with high copper content and added elements of antimony and vanadium.

[0031] (4) GH2132 (US brand A286), 4 pieces, with high nickel content and low copper content, high titanium content and low vanadium content.

[0032] (5) GH2036 iron-based superalloy, 5 pieces, high manganese content

[0033] (6) W18Cr4V high-speed tool steel, 5 pieces, with high tungsten content.

[0034] (7) Low-alloy steel GSBH40067-93, 7 pieces, wit...

Embodiment 2

[0053] Application of nickel base alloy

[0054] Step 1: This embodiment selects the following standard samples:

[0055] (1) GH3044, 5 pieces, high tungsten solid solution strengthened alloy.

[0056] (2) DZ125, 5 pieces, directionally solidified alloy, high tungsten, tantalum, molybdenum, cobalt strengthened solid solution matrix, and contains high content of aluminum and titanium to form Ni3 (Al, Ti) (γ' phase) aging strengthening alloy.

[0057] (3) GH4169 (Inco718 alloy in the United States), 5 pieces, high niobium content, forming a Ni3Nb (γ” phase) strengthening phase, used for turbine disks, compressor disks, compressor blades, etc., is the most used alloy in aero-engines.

[0058] (4) GH4049, 5 pieces, deformed turbine blade material with high content of molybdenum, tungsten, cobalt, aluminum and titanium.

[0059] (5) N263 (China GH163), 5 pieces, solid solution strengthening alloy with high molybdenum and cobalt, combustion chamber materials.

[0060] (6) C1023 (...

Embodiment 3

[0086] Application of Copper Alloy

[0087] Step 1: This embodiment selects the following standard samples:

[0088] (1) Aluminum bronze, 9 pieces, is characterized by a wide range of aluminum, nickel, and paste elements, and there are many types of elements, including 12 elements.

[0089] (2) Silicon brass, 6 pieces, containing sulfur, antimony, bismuth elements and high content of zinc and silicon elements.

[0090] (3) Gun metal, 5 pieces, with high content of tin, lead and zinc elements, and low content of bismuth, silver and antimony.

[0091] (4) Nickel silver, 5 pieces, characterized by a high content of nickel and zinc elements, with a nickel content of 20.9%.

[0092] (5) QA110-4-4 aluminum-iron-nickel bronze, 5 pieces.

[0093]Step 2: Sample preparation: The sample is ground, and the surface is ground into a smooth plane with consistent texture. In order to avoid the interference of the abrasive on the low content of Al and Si elements in the sample preparation,...

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Abstract

The invention relates to an X-ray fluorescent spectrum fundamental parameter method utilizing a virtually synthesized standard sample, belonging to the technical field of X-ray fluorescent spectrum detection. A standard sample is integrated with the fundamental parameter method; appropriate working conditions are selected; the comprehensive application such as effective overlap and correction of spectral lines, background deduction and the like is carried out, so that pure strength values of all elements can be obtained; subsequently a standard sample is virtually synthesized, so that a fundamental parameter method curve manufactured by the virtually synthesized standard sample is established; finally a user can establish a general working curve of the same substrate material by using a few standard samples, so that the accurate detection of components of alloys of the same substrate can be achieved; the fundamental parameter method has a wide analysis range and is not limited by an upper limit and a lower limit of the standard sample; a great quantity of standard samples are not required to be purchased, so that the fundamental parameter method has great economic benefits. The X-ray fluorescent spectrum fundamental parameter method is also applicable to detection of the novel material and capable of meeting detection of novel materials which are developed by research institutions of colleges and universities and the like, and solves the problem of no standard sample of the novel material. The method is wide in application prospect in detection field of X-ray fluorescence spectrophotometers.

Description

technical field [0001] The invention relates to an X-ray fluorescence spectrum basic parameter method for virtually synthesizing standard samples, and belongs to the technical field of X-ray fluorescence spectrum detection. Background technique [0002] The chemical composition in the alloy is complex, and there are many elements that need to be analyzed. The use of chemical methods to analyze samples has the disadvantages of long detection cycle, large amount of manpower consumption, and high detection cost. X-ray fluorescence spectroscopy is widely used in metallurgy, ore, powder and other fields due to its advantages of fast analysis speed, high precision, good accuracy, convenient sample preparation, and non-destructive testing. However, the X-ray fluorescence spectrometry has strict requirements on the standard sample, and the effective methods in the fluorescence spectrum, such as the internal standard method, the standard addition method, the dilution method, the mixe...

Claims

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Application Information

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IPC IPC(8): G01N23/223
Inventor 张环月唐侠金恒松葛新颖权义宽季守华闫秀芬孙健
Owner DALIAN UNIV OF TECH
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