JP5968083B2 - Elemental analyzer - Google Patents

Description

  The present invention relates to an element analyzer for analyzing elements such as oxygen (O), nitrogen (N), and hydrogen (H) contained in measurement samples such as steel, non-ferrous metals, and ceramics.

As a conventional elemental analyzer, as shown in Patent Document 1, a sample is placed in a graphite crucible that is heated by Joule heating by passing an impulse current, the sample is heated and melted, and oxygen (O), nitrogen (N ) And hydrogen (H) are reduced and decomposed with a graphite crucible to generate gas such as carbon monoxide (CO), nitrogen (N ₂ ), hydrogen (H ₂ ). This elemental analyzer uses oxygen (O) in the sample as carbon monoxide (CO) (when analyzing low-concentration oxygen (O) with high accuracy, carbon monoxide ( the CO) is oxidized to carbon dioxide (CO ₂₎ carbon dioxide (as CO _2)), nitrogen (N) and nitrogen (as _{N 2),} hydrogen (hydrogen H) at the subsequent stage of oxidizer _(H 2) is oxidized in _{H 2} O is detected as the _{H 2} O.

  In this elemental analyzer, as shown in FIG. 4, the analysis accuracy of oxygen (O) and hydrogen (H) decreases as the temperature of the graphite crucible increases, while the analysis of nitrogen (N). The accuracy improves as the temperature of the graphite crucible increases. That is, the analysis accuracy of oxygen (O) and hydrogen (H) and the analysis accuracy of nitrogen (N) show opposite behaviors with respect to the heating temperature of the graphite crucible.

Here, in the conventional elemental analyzer, as shown in FIG. 5, the heating temperature of the crucible when extracting the element contained in the sample as a gas component is constant. Then, when the heating temperature of the graphite crucible is set to an optimum temperature for extracting oxygen (O) and hydrogen (H) as gas components, nitrogen (N) is not sufficiently extracted as nitrogen (N ₂ ). Analysis accuracy will deteriorate. On the other hand, when the heating temperature of the graphite crucible is set to an optimum temperature for extracting nitrogen (N) as a gas component, it is contained in the graphite crucible itself in addition to oxygen (O) contained in the sample. Oxygen (O) is extracted, resulting in poor analytical accuracy. Thus, when simultaneous analysis is performed using a single sample, it is extremely difficult to analyze all of oxygen (O), nitrogen (N), and hydrogen (H) with high accuracy.

  Here, when analyzing each element of oxygen (O), nitrogen (N), and hydrogen (H) with high accuracy, a plurality of the same samples are prepared, and the heating temperature of the graphite crucible is set for each sample. It is necessary to analyze each element by heating to an optimum temperature for extraction as a gas component.

  However, such a method requires at least two elemental analyzes, ie, an analysis for analyzing oxygen (O) and hydrogen (H) with high accuracy and an analysis for analyzing nitrogen (N) with high accuracy. There is a problem that the analysis time required for analyzing all the elements with high accuracy takes a long time. In addition, in order to analyze each element with high accuracy, it is necessary to prepare consumables such as a graphite crucible, a carrier gas such as He gas, or a reagent for each elemental analysis, resulting in an increase in cost. .

JP 2000-193657 A

  Therefore, the present invention has been made to solve the above-mentioned problems all at once, and its main intended problem is to analyze each element contained in a sample simultaneously and with high accuracy using a single sample. It is what.

That is, the elemental analysis apparatus according to the present invention heats a sample placed in a crucible in a heating furnace, reduces and decomposes the elements contained in the sample with a crucible , extracts them as gas components, and quantitatively analyzes the elements. A reductive decomposition type elemental analysis apparatus, comprising: a first extraction mode for heating a heating furnace at a first element extraction optimum temperature for extracting a first element contained in the sample as a gas component; A second extraction mode in which a second element different from the first element is extracted as a gas component, and the heating furnace is heated at a second element extraction optimum temperature that is higher than the first element extraction optimum temperature. And is executed in combination.

  In such a case, the first extraction mode for heating the heating furnace at the optimum first element extraction temperature for extracting the first element and the second element extraction optimum for extracting the second element are optimal. By combining the second extraction mode in which the heating furnace is heated at a temperature, the first element and the second element can be extracted under optimum conditions in each mode, so that each element can be accurately obtained using a single sample. Can be analyzed simultaneously. In addition, it is not necessary to prepare multiple samples to analyze each element with high accuracy, and to perform each analysis at the optimum heating temperature for each element, so each element is analyzed with high accuracy. Analysis time can be reduced. Furthermore, consumption of consumables such as a graphite crucible, a carrier gas such as He gas, or a reagent used for analyzing each element with high accuracy can be reduced, and a running cost can be reduced.

  If the second extraction mode that is the second element extraction optimum temperature that is higher than the first element extraction optimum temperature is performed first, the first element contained in the graphite crucible itself is extracted in the first extraction mode, or The extraction of the first element may be insufficient. For this reason, it is desirable to perform the second extraction mode after performing the first extraction mode. For example, when the first element is oxygen (O) and the second element is nitrogen (N), the graphite crucible is heated when heated at the optimum temperature for nitrogen extraction first and then heated at the optimum temperature for subsequent oxygen extraction. It is possible to solve the problem that oxygen contained in itself is extracted to cause an oxygen measurement error.

  The first extraction mode is for heating the heating furnace at an oxygen extraction optimum temperature for extracting oxygen contained in the sample as a gas component, and the second extraction mode is nitrogen contained in the sample. If the heating furnace is heated at a nitrogen extraction optimum temperature for extracting as a gas component, the effect of the present invention will be further improved.

  According to the present invention configured as described above, a plurality of elements contained in a sample can be analyzed simultaneously and with high accuracy using a single sample.

The schematic diagram which shows the structure of the elemental analyzer of this embodiment. The figure which shows the extraction mode of the heating furnace of the embodiment. The figure which shows the heating mode of the heating furnace of deformation | transformation embodiment. The figure which shows the relationship between the heating temperature of a graphite crucible, and the measurement precision of oxygen, nitrogen, and hydrogen. The figure which shows the heating mode of the conventional heating furnace.

  Hereinafter, an elemental analyzer 100 according to the present invention will be described with reference to the drawings.

  The elemental analysis apparatus 100 of the present embodiment heats and melts a metal sample or a ceramic sample (hereinafter also simply referred to as a sample) accommodated in the crucible R, and analyzes the gas component generated at that time, thereby The element contained in the sample is measured.

Specifically, as shown in FIG. 1, this has a flow pipe that forms a single gas flow path 2 through which a sample gas generated in the heating furnace 1 flows along with a carrier gas (for example, He gas), On the distribution pipe, the CO detection unit 3, the oxidation unit 4, the CO ₂ detection unit 5, the H ₂ O detection unit 6, the CO ₂ removal unit 7, the H ₂ O removal unit 8 and the N ₂ detection unit 9 are arranged in this order. It is provided in series.

  The CO detector 3 detects carbon monoxide (CO) contained in the sample gas and measures (detects) the concentration thereof, and is configured by a non-dispersive infrared gas analyzer (NDIR).

The oxidation unit 4 is provided on the downstream side of the CO detection unit 3 and oxidizes carbon monoxide (CO) contained in the sample gas into carbon dioxide (CO ₂ ) and hydrogen (H) into water (H ₂ O). It is oxidized to produce water vapor. The oxidation unit 4 of the present embodiment is configured by using, for example, copper oxide (CuO), specifically, by filling the quartz tube with copper oxide (CuO), and the copper oxide (CuO). Is heated to about 600 degrees. As a heating method of the copper oxide (CuO), a method of heating with a heating resistor, etc. can be considered.

The CO ₂ detection unit 5 detects carbon dioxide (CO ₂ ) contained in the sample gas and measures its concentration, and is constituted by a non-dispersive infrared gas analyzer (NDIR). This CO ₂ detection unit 5 is effective when oxygen (O) contained in the sample has a low concentration (for example, less than 200 ppm) because of its measurement accuracy.

The H ₂ O detection unit 6 detects water (water vapor) contained in the sample gas and measures the concentration thereof, and is configured by a non-dispersive infrared gas analyzer (NDIR).

Incidentally, a flow pipe forming the gas passage which connects the oxidation unit 4, CO ₂ detector 5 and H _{2 O} detection unit 6 is heated above 100 ° C.. Specifically, a heating mechanism made of a heating resistor or the like is provided on the outer peripheral surface of the flow pipe. Thus, the water vapor generated by oxidation unit 4 can be prevented measurement error of H _{2 O} detection unit 6 caused by decreased condensation to reach in H 2 _O detection unit 6. Furthermore, it is possible to prevent the flow pipe from being rusted by condensed water.

The CO ₂ removal unit 7 adsorbs and removes carbon dioxide (CO ₂ ) from the sample gas that has passed through the oxidation unit 6, and does not react, adsorb, or the like with respect to nitrogen (N ₂ ) contained in the sample gas. For example, ascarite or zeolite molecular sieve can be used.

The H ₂ O removal unit 8 adsorbs and removes water (water vapor) from the sample gas that has passed through the oxidation unit 6 and does not react or adsorb to nitrogen (N ₂ ) contained in the sample gas. For example, magnesium perchlorate or calcium chloride can be used.

The N ₂ detector 9 detects nitrogen (N ₂ ) contained in the sample gas and measures the concentration thereof, and is constituted by a thermal conductivity analyzer (TCD).

  The measurement signal (measured value indicating the concentration of each gas component) obtained by each detection unit is output to the calculation unit 10. The calculation unit 10 that has acquired the measurement signal calculates the concentrations of oxygen (O), hydrogen (H), and nitrogen (N) contained in the sample based on each measurement signal. And the calculating part 10 outputs the density | concentration of oxygen (O), hydrogen (H), and nitrogen (N) which is a calculation result to the output part (monitor) which is not shown in figure. The specific configuration of the arithmetic unit 10 is, for example, a general-purpose or dedicated computer including a CPU, an internal memory, an input / output interface, an AD converter, and the like, and is based on a program stored in a predetermined area of the internal memory. When the CPU and its peripheral devices are operated, the concentrations of oxygen (O), hydrogen (H) and nitrogen (N) are calculated. The arithmetic unit 10 may be configured using a discrete analog circuit using a buffer, an amplifier, a comparator, or the like without using a computer.

Thus elemental analyzer 100 of the present embodiment, as shown in FIG. 2, the furnace 1 oxygen (O) is the first element contained in the sample with oxygen extraction optimum temperatures T ₁ to be extracted as a gas component And a second element extraction optimum temperature T ₂ that is higher than the oxygen extraction optimum temperature T ₁ for extracting nitrogen (N), which is the second element contained in the sample, as a gas component. The second extraction mode for heating the heating furnace 1 is executed in combination. FIG. 2 also shows changes with time in measured concentration values of oxygen (O), nitrogen (N), and hydrogen (H) obtained when the first extraction mode and the second extraction mode are executed.

  Specifically, the control device 11 that controls a heating mechanism (not shown) provided in the heating furnace 1 continuously controls the heating mechanism by combining the first extraction mode and the second extraction mode. Let it run. That is, the control device 11 executes the second extraction mode after performing the first extraction mode. In addition, the heating mechanism of this embodiment has an upper electrode and a lower electrode that sandwich the graphite crucible R from above and below, and a power source that applies an impulse current to these electrodes. And the control apparatus 11 performs the said 1st extraction mode and 2nd extraction mode by controlling the power supply of a heating mechanism.

The first extraction mode is a mode in which the graphite crucible R is heated at a heating temperature T ₁ (for example, 2000 ° C.) and a heating time S ₁ (for example, 20 seconds) optimal for extracting oxygen (O) contained in the sample. It is. In the first extraction mode, oxygen (O) contained in the sample is extracted as carbon monoxide (CO), and hydrogen (H) contained in the sample is extracted as water (H ₂ O). At the same time, nitrogen (N) contained in the sample is extracted as nitrogen (N ₂ ).

In the second extraction mode, the graphite crucible R is heated at a heating temperature T ₂ (for example, 2500 ° C.) and a heating time S ₂ (for example, 20 seconds) that are optimal for extracting nitrogen (N) contained in the sample. It is. In the second extraction mode, nitrogen (N) that could not be extracted from the sample in the first extraction mode is extracted as nitrogen (N ₂ ) (shaded area in FIG. 2). Incidentally, the hatched portion in FIG. 2, in the case of constant heating at an oxygen optimum temperatures T ₁ by conventional elemental analysis device is a part which is not extracted. On the other hand, the measurement error will be extracted oxygen contained in the graphite crucible itself when certain heated in a nitrogen optimum temperature T ₂ by a conventional elemental analysis device.

According to the elemental analysis device 100 according to this embodiment configured as described above, oxygen (O) the first extraction mode and nitrogen to heat the furnace 1 at the optimum oxygen extraction optimum temperatures T ₁ to extract the (N ) by combining the second extraction mode for heating the heating furnace 1 at the optimum nitrogen extracted optimum temperature T ₂ for extracting, extracting oxygen (O) and nitrogen (N) at the optimum conditions in each mode Therefore, each element (oxygen and nitrogen) can be simultaneously analyzed with high accuracy using a single sample. In addition, it is not necessary to prepare multiple samples to analyze oxygen and nitrogen with high precision, and to perform multiple analyzes of heating at the optimal heating temperature for each element. Analyzing time can be shortened. Furthermore, the consumption of consumables such as graphite crucible R, a carrier gas such as He gas, or a reagent used for analyzing each element with high accuracy can be reduced, and the running cost can be reduced.

  The present invention is not limited to the above embodiment. For example, in the above embodiment, both oxygen and hydrogen contained in the element are quantitatively analyzed, but only one of oxygen and hydrogen may be quantitatively analyzed.

  Further, only one of the first extraction mode and the second extraction mode may be executed according to the type of sample. For example, it is possible to switch between a pattern in which the first extraction mode and the second extraction mode are executed in one analysis step and a pattern in which only one of the first extraction mode or the second extraction mode is executed according to the type of sample. It may be configured.

  Furthermore, in the said embodiment, although 1st extraction mode and 2nd extraction mode were each performed once, you may perform by repeating them alternately several times.

Moreover, in the embodiment, in a thing that changes from oxygen abstraction optimum temperature T ₁ of the first extraction mode to the second extraction mode nitrogen extracted optimum temperature T ₂ stepwise (stepwise) in FIG. 3 As shown, it may have a transition mode in which the heating temperature of the graphite crucible is smoothly and continuously changed between the first extraction mode and the second extraction mode.

  In addition to the graphite crucible, a ceramic crucible may be used. In this case, the elemental analysis apparatus includes a high-frequency heating furnace, and may analyze carbon, sulfur, etc. present in the sample.

  Moreover, the combination of extraction modes, temperature, or order may be automatically controlled by the control unit 11 by designating a measurement target element included in a measurement sample.

  In addition, it goes without saying that the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention.

100 ... elemental analyzer R ... crucible 1 ... furnace _T 1 ... first element extraction optimum temperature (oxygen extraction optimum temperature)
T ₂ ... second element extraction optimum temperature (nitrogen extraction optimum temperature)

Claims (3)

A reductive decomposition type elemental analyzer that heats a sample in a graphite crucible in a heating furnace, reductively decomposes the elements contained in the sample with a graphite crucible , extracts them as gas components, and quantitatively analyzes the elements. There,
A first extraction mode in which a graphite crucible is heated at a preset first element extraction optimum temperature for extracting the first element contained in the sample as a gas component; and the first element contained in the sample; Is to extract different second elements as gas components, and is combined with a second extraction mode in which the graphite crucible is heated at a preset second element extraction optimum temperature that is higher than the first element extraction optimum temperature. Elemental analyzer characterized by being executed.   The elemental analyzer according to claim 1, wherein the second extraction mode is performed after the first extraction mode is performed. The first extraction mode is to heat the graphite crucible at a preset optimum oxygen extraction temperature for extracting oxygen contained in the sample as a gas component,
3. The elemental analysis apparatus according to claim 1, wherein the second extraction mode heats the graphite crucible at a preset optimum nitrogen extraction temperature for extracting nitrogen contained in the sample as a gas component.