Atomic Emission Spectrometry Method for Measuring Trace Beryllium in Aluminum Alloys

A technology of atomic emission spectroscopy and aluminum alloy, which is applied in the field of atomic emission spectrometry analysis and measurement of trace beryllium in aluminum alloy, which can solve the problems of many ions, the influence of the third element, and the inability to meet the quantitative detection of aluminum alloy, etc.

Active Publication Date: 2021-06-08
颜长明
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  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0005] Evaporation and excitation are highly sensitive in spectroscopic analysis, but when measuring trace amounts of beryllium in aluminum alloys, due to the high content of third elements (such as Mg, Zn, Cu), the atoms and ions generated when these third elements are excited, and the transition energy Large, affecting the excited state of trace elements (such as beryllium), there is a more serious influence of the third element and the influence of aluminum alloy structure
Due to the influence of the third element, special standard samples and specific spectral analysis methods need to be used for different types of aluminum alloys; due to the influence of aluminum alloy structures, standard samples and sample structures must be maintained for different types of aluminum alloys. Consistent, resulting in the inability to meet and use spectral analysis to quantitatively detect the content of trace elements in aluminum alloys
The above-mentioned limitations of spectral analysis have seriously affected the application of spectral analysis in the determination of trace elements in aluminum alloys.

Method used

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  • Atomic Emission Spectrometry Method for Measuring Trace Beryllium in Aluminum Alloys
  • Atomic Emission Spectrometry Method for Measuring Trace Beryllium in Aluminum Alloys
  • Atomic Emission Spectrometry Method for Measuring Trace Beryllium in Aluminum Alloys

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0033] instrument

[0034]The model of the spectrograph is QL-170, the photosensitive plate is Type I photosensitive plate, the light source is US-1, the total resistance of the light source is 78Ω, the spark resistance is 7.9Ω, the phaser is set to +6.6°, and the intermittent arc resistance is 23Ω. Spark current 4A, arc voltage 220V, arc current 12A, spark voltage 55V. The slit width is 20 μm, the lens is selected from three lenses, and the wavelength of the characteristic spectrum is selected from 220.0-280.0 nm.

[0035] Beryllium spectral standard

[0036] LF 2 6 # , LY 2 7 # , LY 4 10 # Aluminum alloy is the procurement standard sample, among which, LF 2 6 # Anti-rust aluminum, anti-rust aluminum is Al-Mg alloy, Mg content 2.05-2.50%; LY 2 7 # It is hard aluminum, and hard aluminum is Al-Cu-Mg-Mn alloy, with Cu content of 2.70-3.10%, Mg content of 2.00-2.40%, and Mn content of 0.45-0.70%; LY 4 10 # It is hard aluminum, and hard aluminum is an Al-Cu-Mg-M...

Embodiment 2

[0045] The parameters are the same as in Example 1. The upper electrode of the spectrograph is made of high-purity copper with a purity of 99.99% and processed into a flat-topped cone with a diameter of 6-8mm and a cone angle of 30°. It is the discharge plane of 0.5mm. Take the LC-10 aluminum alloy sample numbered 4-1253-1 of the same specifications as the beryllium spectral standard sample as the lower electrode, and process the end face corresponding to the upper electrode into a plane by lathe. The aluminum alloy sample was clamped at the lower electrode of the spectrograph, and the spectroscopic analysis was carried out using the same spectroscopic conditions as the beryllium spectral standard sample, and the spectroscopic analysis was repeated four times.

[0046] Substituting the obtained aluminum alloy sample beryllium spectral lines into the standard curve, the calculated content of beryllium in the aluminum alloy sample is 0.00088%, 0.0009%, 0.00088%, 0.00096%, and th...

Embodiment 3

[0048] The parameters are the same as in Example 1. The upper electrode of the spectrograph is made of high-purity copper with a purity of 99.99% and processed into a flat-topped cone with a diameter of 6-8mm and a cone angle of 30°. It is the discharge plane of 0.5mm. Take the LC-10 aluminum alloy sample numbered 4-1253-2 of the same specifications as the beryllium spectral standard sample as the lower electrode, and process the end face corresponding to the upper electrode into a plane by lathe. The aluminum alloy sample was clamped at the lower electrode of the spectrograph, and the spectroscopic analysis was carried out using the same spectroscopic conditions as the beryllium spectral standard sample, and the spectroscopic analysis was repeated four times.

[0049] Substituting the obtained beryllium spectral lines of the aluminum alloy sample into the standard curve, the calculated content of beryllium in the aluminum alloy sample is 0.00097%, 0.00089%, 0.00086%, 0.00098%...

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Abstract

Atomic emission spectrometry is a method for measuring trace amounts of beryllium in aluminum alloys. The upper electrode is made of high-purity copper or high-purity carbon with a diameter of 6-8mm. The beryllium spectral standard sample / aluminum alloy sample is the lower electrode, and the upper electrode is the cone angle. 30° flat-topped cone, the top surface is a discharge plane with a diameter of 0.5mm, the discharge plane of the upper electrode corresponds to the plane of the lower electrode and the pole distance is 1.9mm or 1.8mm, the total resistance of the light source is 75‑80Ω, and the spark resistance 7‑9Ω, spark current 4‑4.5A, arc voltage 220V, arc current 10‑12A, phaser +6‑7°, intermittent arc resistance 20‑25Ω, spark voltage 55V, The slit width of the spectrometer is 20μm, pre-burning 10-15s, exposure 10-15s, developing at 20±1°C for 4-7min, fixing for 5-10min, and recording each beryllium spectral standard sample / aluminum alloy sample through the photosensitive plate Beryllium spectral lines.

Description

technical field [0001] The invention relates to the field of quantitative analysis of trace elements in aluminum alloys, in particular to a method for measuring trace beryllium in aluminum alloys by atomic emission spectrometry. Background technique [0002] Aluminum alloy is the most widely used non-ferrous metal alloy material in industry, and it is widely used in aviation, aerospace, machinery manufacturing, shipbuilding and chemical industry. Aluminum alloys usually contain 1-10 ppm of trace beryllium elements, and chemical analysis or spectral analysis is usually used to determine the content of trace beryllium elements in aluminum alloys. [0003] When chemical analysis is used to quantitatively analyze the trace amount of beryllium in aluminum alloy, it is necessary to process the sample powder, weigh the sample, dissolve the sample, and then react to detect the content of beryllium element through reagent preparation. Chemical analysis takes a long time, and due to ...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): G01N21/67
CPCG01N21/67
Inventor 颜长明程淇
Owner 颜长明
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