JP3105385B2 - High frequency induction heating device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of measuring the concentration of carbon, sulfur, etc. in an analytical sample by burning an analytical sample placed in an oxygen stream with an induction heating furnace. The present invention relates to a high-frequency induction heating device supplied to an infrared gas analyzer.

[0002]

2. Description of the Related Art Conventionally, in order to measure the concentration of, for example, carbon, sulfur, etc. in a sample, an analysis sample is burned by high-frequency induction heating to generate an oxidizing gas, which is analyzed by an infrared gas analyzer. A way is being considered. FIG.
It is a figure which shows the conventional high frequency induction heating apparatus, 10 in FIG.
Indicates a high-frequency induction heating device.

[0003] In FIG. 3, reference numeral 2 denotes an induction heating furnace. For example, large, medium, and small high-frequency power supplies 61, 62, and 63 are selectively selected to the induction heating furnace 2 via a changeover switch 60, and while supplying high-purity oxygen, By heating and burning the analysis sample, CO, S can be removed from each of the C and S components contained in the sample.
An oxidizing gas of CO ₂ and SO ₂ is generated and supplied to an infrared gas analyzer (not shown) for analysis.

[0004]

However, in this conventional high-frequency induction heating apparatus, for example, large, medium, and small high-frequency power supplies 61, 62, and 63 are selectively selected. The range of the product is narrow, and the actual usage of the product is almost always fixed to one of the three power sources and used.

On the other hand, since the heating and combustion of an analysis sample largely depends on the characteristics of the sample, when the analysis sample is fixed to one high-frequency power source as described above, the analysis sample rapidly reacts with oxygen in the combustion process. In some cases, the sample is bumped and scattered due to bumping, or conversely, unburned, which adversely affects the accuracy of analytical values.

The present invention has been made in view of the above points, and it is an object of the present invention to always burn an analytical sample in a stable state with an optimum heating pattern and to improve the accuracy of gas obtained by burning. It is an object of the present invention to provide a high-frequency induction heating device that can perform heating.

[0007]

That is, the present invention relates to a high-frequency induction heating apparatus in which a sample is burned by using high-frequency induction heating .
Is characterized by comprising an output setting device that automatically controls the high frequency power supply unit based on the heating pattern sample set Me optimally you heat combustion pre prevent such unburned. Further, from another viewpoint, the present invention provides a high-frequency induction heating apparatus in which high-frequency induction heating is used to burn a sample, wherein the deflagration, bumping, scattering, unburning, etc. of the sample are prevented.
A state in which the high-frequency power supply unit is automatically controlled based on a preset heating pattern that optimally heats and burns, and a state in which the heating pattern can be changed, and a high-frequency power supply unit is manually controlled. Furthermore, when the heating pattern for heating and burning the sample is changed by manual control, a memory for storing the changed heating pattern is provided, and the high-frequency power supply unit is automatically activated based on the same heating pattern as the stored heating pattern. It is characterized in that it is configured to control.

[0008]

According to the present invention, by automatically controlling the high-frequency power supply unit based on a preset heating pattern, it is possible to always supply the optimum high-frequency power according to the analysis sample, and to achieve the deflagration of the sample. Thus, stable combustion gas can be extracted by preventing bumping, scattering, unburned and the like, and accurate analysis can be performed. In addition, even for an analysis sample that is difficult to burn, there is no need to use an extra combustion aid, and the amount of dust generated during combustion can be minimized.

On the other hand, by switching to manual control, it is possible to find out an optimal heating pattern when, for example, burning an unknown analytical material.

[0010]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a view showing a high-frequency induction heating apparatus according to one embodiment of the present invention, in which 1 indicates a high-frequency induction heating apparatus, and the high-frequency induction heating apparatus 1 includes an induction heating furnace 2 and a high-frequency induction heating apparatus. It comprises a power supply unit 3, a power supply unit 4, and an output setting device 5.

An analysis sample is introduced into the induction heating furnace 2, and the sample is heated and burned while supplying high-purity oxygen. An oxidizing gas such as CO ₂ and SO ₂ is generated, and the oxidizing gas is supplied to an infrared gas analyzer (not shown) for analysis.

The high-frequency power supply unit 3 comprises a solenoid 30, capacitors 31, 32 and an amplifier 33. The capacitors 31, 32 and the solenoid 30 form a high-frequency resonance circuit, and the amplifier 33 promotes this resonance. It is provided for. 34 is a high-frequency power supply unit 3
This is a choke coil for preventing a high frequency component generated by the influence from affecting a power supply unit 4 described later.

The power supply section 4 supplies a variable DC current to the high-frequency power supply section 3, and includes a triac 40, which is an AC switching element, a trigger circuit 41, a power transformer 44, a rectifying bridge 43, and a current monitor 42. And power input terminals 47 and 48. Also,
The transformer 44 has a primary coil 45 and a secondary coil 46.

The power supply section 4 has power supply input terminals 47, 4
8 is connected to a commercial power supply of AC 200V,
The AC power supplied between the terminals is switched by the triac 40 ignited by the firing angle calculated by the trigger circuit 41 and is input to the primary coil 45 of the transformer 44. A current is induced in the secondary coil 46 due to the current flowing through the primary coil 45, and the current is converted to DC by the rectifying bridge 43, whereby a variable DC current is supplied to the high-frequency power supply unit 3. You.

The output setting device 5 includes an automatic control device 51
The trigger circuit 41 of the power supply unit 4 can output a firing signal of the triac 40 based on a control signal from the output setting device 5. In other words, the power supplied to the induction heating furnace 2 can be arbitrarily changed by controlling the high-frequency power supply unit 3 via the power supply unit 4 by changing the output of the output setting device 5.

The automatic control device 51 stores the power to be supplied to the induction heating furnace 2 prepared in advance, that is, the heating pattern of the induction heating furnace 2 in accordance with the type and quantity of the analysis sample. Automatic control device 51
In this case, the power supplied to the induction heating furnace 2 is controlled by an optimal heating pattern prepared in advance, so that optimal combustion can always be performed on the analysis sample.

On the other hand, when the changeover switch 50 is switched to the manual control device, the heating pattern of the induction heating furnace 2 can be freely changed by the analysis operator. Can manually find the optimal heating pattern. It is also possible to switch to manual operation during the analysis at the stage of performing the analysis by automatic control. The heating pattern can be stored in a memory in the automatic control device 51, and the automatic control device 51 can repeatedly analyze the same pattern.

FIG. 2 shows that one component contained in a specific analysis sample is heated and heated using the induction heating apparatus 1 of the present embodiment.
It is a graph which shows an example of the specific heating pattern suitable for the kind and quantity of the sample prepared for combustion. Therefore, the operation of controlling the induction heating device 1 shown in FIG. 1 by the output setting device 5 according to the heating pattern shown in the graph of FIG. 2 will be described below.

In FIG. 2, the horizontal axis of the graph indicates the time from the start of the heating operation.
Is a curve showing electric power supplied to the solenoid 30, and 9 is a curve showing the amount of combustion gas obtained by burning the analysis sample. The automatic controller 51 controls the high-frequency power supply unit 3 via the power supply unit 4 in accordance with the size indicated by the curve 8 so that the analysis sample can be heated and burned in an optimal manner.

When the analysis sample is to be heated and burned according to the preset heating pattern, the changeover switch 50 is switched to the automatic control device 51 side. Then, the output setting device 5 inputs the type and amount of the analysis sample to the automatic control device 51, and controls the high-frequency power supply unit 3 via the power supply unit 4 according to the unique heating pattern stored in the internal storage device. This controls the electric power for heating the induction heating furnace 2.

First, power W ₂ is supplied to the induction heating furnace 2 to heat the analysis sample. The heated analysis sample combines with oxygen at T ₁ and starts burning. This T
Lowering the heating power to W ₁ at _1. The analysis sample is spontaneously heated by the heat of oxidation generated during combustion, thereby promoting combustion and extracting gas. Wherein the power W ₁ is the power necessary to accelerate the combustion.

Next, the automatic control unit 51 increases the power at the time of T ₂ was confirmed in that the gas has been extracted to W _3, forcibly burning the remaining components can not be extracted with spontaneous combustion of the aforementioned To extract gas.

That is, according to the high-frequency induction heating apparatus of the present invention, the high-frequency power supply unit 3 provides the optimum high-frequency power to the induction heating furnace 2 according to the amount and type of the sample to be analyzed, so that deflagration and bumping of the sample can be achieved. Thus, stable combustion gas can be extracted by preventing scattering, unburned and the like, and accurate analysis can be performed.

When an analysis sample that is difficult to burn is used, an optimal heating pattern corresponding to the analysis sample is prepared in advance, and heating is performed based on the heating pattern, so that an extra combustion aid is used. No need to do.

Furthermore, even when using an analysis sample that generates a large amount of dust during combustion, the amount of dust can be reduced as much as possible by controlling the high-frequency power supply unit 3 based on a heating pattern suitable for the sample.

In addition, when burning an unknown analysis sample, the changeover switch 50 is switched to the manual control device 52 so that the high-frequency power supply unit 3
Can be changed freely by the analysis operator. Further, even when heating according to the heating pattern is being performed by the automatic control device 51, the adjustment of the heating power can be manually performed by switching the switch 50.

In this case, it is easy to form a new heating pattern by storing the manually operated operation in the control device 51.

[0028]

As described in detail above, according to the present invention,
Since the high-frequency power supply is automatically controlled based on a preset heating pattern, deflagration, bumping, scattering,
By preventing unburning, etc., combustion can be performed in a stable state with an optimal heating pattern always according to the sample, and the accuracy of generated gas obtained by combustion can be improved.

When an analysis sample that is difficult to burn or an analysis sample that generates a large amount of dust during combustion is used, an optimal heating pattern is prepared in advance for each analysis sample. By following the pattern, the amount of dust can be minimized without having to use an extra combustion aid.

In addition, when an unknown analysis sample is burned, the analysis operator can freely change the high-frequency power supply unit by switching to manual operation, so that an optimum heating pattern can be found. Further, even during the heating according to the heating pattern, the heating can be performed manually.

[Brief description of the drawings]

FIG. 1 is a diagram showing a high-frequency induction heating device of the present invention.

FIG. 2 is a graph showing an example of a heating pattern using the high-frequency induction heating device of the present invention.

FIG. 3 is a diagram showing an output switching circuit and an induction heating furnace in a conventional induction heating furnace.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Induction heating device, 2 ... Induction heating furnace, 3 ... High frequency power supply part, 5 ... Output setting device.

Claims (2)

(57) [Claims] 1. A high-frequency induction heating apparatus so as to utilize the high frequency induction heating burning the sample, the sample bomb
Retardant, bumping, scattering, high frequency induction, characterized in that an output setting device that automatically controls the high frequency power supply unit based on the heating pattern set pre Me you optimum heat burning the sample to prevent such unburned Heating equipment. 2. A high-frequency induction heating apparatus so as to utilize the high frequency induction heating burning the sample, the sample bomb
Optimally heats sample while preventing burning, bumping, scattering, unburned, etc.
It is configured to be switchable between a state in which the high-frequency power supply unit is automatically controlled based on a preset heating pattern for burning and a state in which the heating pattern can be changed and a high-frequency power supply unit is manually controlled. When the heating pattern for heating and burning is changed by manual control, a memory for storing the changed heating pattern is provided, and the high-frequency power supply unit is automatically controlled based on the same heating pattern as the stored heating pattern. A high-frequency induction heating device characterized by being constituted.