KR100786240B1 - Apparatus and method for automatic classification of contaminated organic solvent using infrared spectrometer - Google Patents

Abstract

The present invention is to provide an automatic classification device of a contaminated organic solvent using an infrared spectrometer and a method thereof, comprising: a constant pressure pump for supplying an organic solvent; A constant temperature chamber for chemically stabilizing the organic solvent supplied from the constant pressure pump; An infrared light source unit for irradiating an infrared light source; A continuous flow cell unit receiving the organic solvent stabilized in the constant temperature chamber and irradiating the organic solvent with the infrared light of the infrared light source unit; An optical separation unit separating the wavelength of the infrared light emitted from the continuous flow cell unit; And a pollution degree classifying unit for classifying the pollution degree of the organic solvent by detecting a spectrum of the wavelength of the light separated by the optical separation unit. By including an infrared spectrometer, the spectroscopic characteristics of the organic solvent are detected and the detected data is detected. It is possible to determine whether to reuse the organic solvent by measuring the pollution degree of the organic solvent being used by interpreting.

Infrared Spectroscopy, Organic Solvent, Automatic Sorting, Constant Temperature Chamber, Constant Pressure Pump

Description

Apparatus and method for automatic classification of contaminated organic solvent using infrared spectrometer

1 is a block diagram of an automatic classification device of a contaminated organic solvent using an infrared spectrometer according to an embodiment of the present invention.

2 is a conceptual diagram illustrating a configuration example of FIG. 1.

3 is a flowchart illustrating a method for automatically classifying a contaminated organic solvent using an infrared spectrometer according to an embodiment of the present invention.

Figure 4 is a waveform diagram showing an example of measuring a specific wavelength for each organic solvent according to the present invention.

<Description of Symbols for Main Parts of Drawings>

10: constant pressure pump 20: constant temperature chamber

30: infrared light source unit 40: continuous flow cell unit

50: optical separation unit 60: pollution degree classification unit

61 detection unit 62 signal control and amplification unit

63: calculation unit 64: control and output unit

70: organic solvent management unit

The present invention relates to the automatic classification of contaminated organic solvents, and in particular, by detecting the spectroscopic characteristics of the organic solvent using an infrared spectrometer and interpreting the detected data to measure the degree of contamination of the organic solvent in use whether or not to reuse the organic solvent. The present invention relates to an automatic classification device of a contaminated organic solvent using an infrared spectroscopy apparatus and a method thereof.

In general, an organic solvent refers to a liquid organic compound capable of dissolving a solid, a gas, and a liquid, such as methanol and benzene.

Therefore, conventionally, gas chromatographs, which are expensive analysis equipments, are used for the analysis of solvents at workplaces (business laundry plants and similar companies) using organic solvents.

However, there is no device for easily measuring the pollution degree of the organic solvent in the laundry apparatus using such an organic solvent.

Conventionally, in order to measure the degree of contamination of organic solvents, it has been resorted to a method of checking the organic solvent samples in transparent tubes.

By this observation method, there was a limit that it is impossible to accurately measure the degree of contamination according to the pollutant included in the absorption wavelength range in the ultraviolet range and low visible light, which are characteristic of the organic solvent.

Accordingly, the present invention has been proposed to solve the conventional problems as described above, and an object of the present invention is to detect the spectroscopic characteristics of the organic solvent by using an infrared spectrometer and to interpret the detected data. An object of the present invention is to provide an automatic classification apparatus of a contaminated organic solvent using an infrared spectroscopy device capable of determining the reuse of the organic solvent by measuring the degree of contamination, and a method thereof.

In order to achieve the above object, the automatic classification device of the contaminated organic solvent using an infrared spectrometer according to an embodiment of the present invention, a static pressure pump for supplying an organic solvent; A constant temperature chamber for chemically stabilizing the organic solvent supplied from the constant pressure pump; An infrared light source unit for irradiating an infrared light source; A continuous flow cell unit receiving the organic solvent stabilized in the constant temperature chamber and irradiating the organic solvent with the infrared light of the infrared light source unit; An optical separation unit separating the wavelength of the infrared light emitted from the continuous flow cell unit; And a pollution degree classification unit for classifying a pollution degree of the organic solvent by detecting a spectrum of wavelengths of the light separated by the optical separation unit.

In order to achieve the above object, an automatic classification method of a contaminated organic solvent using an infrared splitter according to an embodiment of the present invention, injecting an organic solvent into a tube having a predetermined width, and supplying the injected solvent at a constant pressure A first step of doing; A second step of irradiating the organic solvent with an infrared light source after the first step; And a third step of detecting the contamination level of the organic solvent by detecting light irradiated after the second step.

Hereinafter, an embodiment according to the present invention as described above, the automatic classification device of the contaminated organic solvent using the infrared spectroscopy method and the technical idea of the method will be described with reference to the drawings.

FIG. 1 is a block diagram of an automatic classification device of a contaminated organic solvent using an infrared spectrometer according to an embodiment of the present invention, and FIG. 2 is a conceptual diagram illustrating a configuration example of FIG. 1.

As shown therein, a constant pressure pump 10 for supplying an organic solvent; A constant temperature chamber 20 for chemically stabilizing the organic solvent supplied from the constant pressure pump 10; An infrared light source unit 30 for irradiating an infrared light source; A continuous flow cell unit 40 receiving the stabilized organic solvent from the constant temperature chamber 20 and irradiating the organic solvent supplied with the infrared ray of the infrared light source unit 30; An optical separation unit 50 for separating the wavelength of the infrared light irradiated onto the continuous flow cell unit 40; And a pollution degree classifying unit 60 for classifying a pollution degree of the organic solvent by detecting a spectrum of wavelengths of the light separated by the optical separation unit 50.

The constant pressure pump 10 is characterized by supplying an organic solvent containing fresh oil or used oil.

The pollution degree classification unit 60 includes: a detection unit 61 for detecting a spectrum of wavelengths of light separated by the optical separation unit 50; A signal control and amplifying section 62 for controlling and amplifying the signal detected by the detecting section 61; An operation unit 63 for performing an operation for classifying pollution degree on the signal amplified by the signal control and amplification unit 62; And a control and output unit 64 which receives the result calculated by the operation unit 63 to quantify the degree of contamination of the organic solvent and outputs the result.

The automatic classification device of the contaminated organic solvent using the infrared spectrometer, the organic solvent management unit 70 for managing the organic solvent according to the pollution degree of the organic solvent classified in the pollution degree classification unit 60; do.

In addition, the automatic classification device of the contaminated organic solvent using an infrared spectrometer, the positive pressure pump 10 for supplying an organic solvent including fresh oil or oil used; A constant temperature chamber 20 for chemically stabilizing the organic solvent supplied from the constant pressure pump 10; An infrared light source unit 30 for irradiating an infrared light source; A continuous flow cell unit 40 receiving the stabilized organic solvent from the constant temperature chamber 20 and irradiating the organic solvent supplied with the infrared ray of the infrared light source unit 30; An optical separation unit 50 for separating the wavelength of the infrared light irradiated onto the continuous flow cell unit 40; A pollution degree classification unit 60 for detecting a spectrum of wavelengths of the light separated by the optical separation unit 50 to classify the pollution degree of the organic solvent; And an organic solvent management unit 70 for managing the organic solvent according to the pollution degree of the organic solvent classified by the pollution degree classification unit 60. The pollution degree classification unit 60 is separated from the optical separation unit 50. A detection unit 61 for detecting a spectrum of light; A signal control and amplifying section 62 for controlling and amplifying the signal detected by the detecting section 61; An operation unit 63 for performing an operation for classifying pollution degree on the signal amplified by the signal control and amplification unit 62; And a control and output unit 64 which receives the result calculated by the operation unit 63 to quantify the degree of contamination of the organic solvent and outputs the result.

3 is a flowchart illustrating a method for automatically classifying a contaminated organic solvent using an infrared spectrometer according to an embodiment of the present invention.

As shown therein, a first step (ST1 to ST3) of injecting an organic solvent into a tube having a predetermined width and supplying the injected solvent at a constant pressure; A second step (ST4) of irradiating the organic light source with the infrared light source after the first step; And a third step (ST5 to ST7) of detecting the pollution level of the organic solvent by detecting the light irradiated after the second step.

The organic solvent in the first step is characterized in that the new oil or used oil.

The first step includes: an eleventh step (ST1) of injecting an organic solvent into a tube having a predetermined width; A twelfth step ST2 of supplying a solvent injected after the eleventh step at a constant pressure; And a thirteenth step (ST3) of chemically stabilizing the organic solvent in the constant temperature chamber 20 after the twelfth step.

The third step includes a twenty-first step (ST5) for separating the light irradiated to the organic solvent after the second step; A twenty-second step ST6 of detecting a spectrum of the wavelength of the separated light after the twenty-first step; And a twenty-third step (ST7) of calculating the spectrum detected after the twenty-second step to check the contamination level of the organic solvent and outputting the result.

In addition, the automatic classification method of the contaminated organic solvent using the infrared spectroscopy, the fourth step (ST8) to manage the organic solvent according to the pollution degree of the organic solvent classified in the organic solvent management unit 70 after the third step; It is characterized by performing.

In addition, the automatic classification method of the contaminated organic solvent using the infrared spectroscopy apparatus of the present invention, the 31 st step (ST1) of injecting the organic solvent containing fresh oil or used oil into a tube having a certain width; A thirty-second step (ST2) of supplying a solvent injected after the thirty-first step with a positive pressure; A thirty-third step ST3 for chemically stabilizing the organic solvent in the constant temperature chamber 20 after the thirty-second step; A thirty-fourth step (ST4) of irradiating the organic light source with an infrared light source after the thirty-third step; A thirty-fifth step (ST5) of separating the light irradiated to the organic solvent after the thirty-fourth step; A thirty sixth step ST6 of detecting a spectrum of the wavelength of the light separated after the thirty-fifth step; A thirty-seventh step (ST7) of calculating a spectrum detected after the thirty-sixth step to check the contamination level of the organic solvent and outputting the result; And a thirty-eighth step (ST8) for managing the organic solvent according to the pollution degree of the organic solvent classified in the organic solvent manager 70 after the thirty-seventh step.

The automatic classification device of the contaminated organic solvent and the method using the infrared spectrometer according to the present invention configured as described above will be described in detail with reference to the accompanying drawings. In the following description of the present invention, detailed descriptions of well-known functions or configurations will be omitted if it is determined that the detailed description of the present invention may unnecessarily obscure the subject matter of the present invention. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to intention or precedent of a user or an operator, and thus, the meaning of each term should be interpreted based on the contents throughout the present specification. will be.

First, the present invention is to determine the reuse of the organic solvent by measuring the pollution degree of the organic solvent in use by detecting the spectroscopic characteristics of the organic solvent using an infrared spectrometer and interpreting the detected data.

FIG. 1 is a block diagram of an automatic classification device of a contaminated organic solvent using an infrared spectrometer according to an embodiment of the present invention, and FIG. 2 is a conceptual diagram illustrating a configuration example of FIG. 1.

Thus, the present invention can be composed of a constant pressure pump 10, constant temperature chamber 20, infrared light source unit 30, continuous flow cell unit 40, light separation unit 50, pollution degree classification unit 60, The organic solvent manager 70 may be added.

Here, the constant pressure pump 10 may supply the organic solvent which is fresh oil or used oil at a constant pressure to measure the degree of contamination.

In addition, the constant temperature chamber 20 chemically stabilizes the organic solvent supplied from the constant pressure pump 10 so that no other side effects occur when measuring the degree of contamination.

In addition, the infrared light source unit 30 may irradiate the infrared light source with the continuous flow cell unit 40 to detect the wavelength of the organic solvent to analyze the spectral wavelength.

In addition, the continuous flow cell unit 40 receives the organic solvent stabilized in the constant temperature chamber 20, and configures the sample cell to irradiate the organic solvent supplied with the infrared ray of the infrared light source unit 30.

The organic solvent passed through the constant pressure pump 10, the constant temperature chamber 20, and the continuous flow cell part 40 is fed back to the fresh oil tank and the used oil tank and circulated to enter the constant pressure pump 10 again.

In addition, the optical separation unit 50 separates the wavelength of the infrared light irradiated to the continuous flow cell unit 40 and transmits the pollution degree classification unit 60.

In addition, the pollution degree classifying unit 60 classifies the pollution degree of the organic solvent by detecting a spectrum of the wavelength of the light separated by the optical separation unit 50. The detection unit 61, the signal control and amplifying unit 62, and the calculating unit 63 ), And the control and output unit 64 can be configured.

Therefore, the detection unit 61 in the pollution degree classification unit 60 detects the spectrum of the wavelength of the light separated by the optical separation unit 50 and transmits it to the signal control and amplification unit 62.

In addition, the signal control and amplifier 62 controls the signal detected by the detector 61, amplifies the weak signal, and transmits the weak signal to the calculator 63.

In addition, the operation unit 63 performs an operation for classifying the pollution degree on the signal amplified by the signal control and amplifying unit 62 and transmits the result to the control and output unit 64.

In addition, the control and output unit 64 receives the result calculated by the operation unit 63 to quantify the pollution degree of the organic solvent and output the result. In addition, if necessary, the organic solvent management unit 70 transmits the result.

In addition, the organic solvent management unit 70 performs operations necessary for the management of the organic solvent according to the pollution degree of the organic solvent classified in the pollution degree classification unit 60.

Figure 4 is a waveform diagram showing an example of measuring a specific wavelength for each organic solvent according to the present invention.

Therefore, the present invention automatically measures the pollution degree of the organic solvent by the correlation between the light intensity and the concentration of the substance using the law of Lambert-Beer's law widely applied to spectroscopy theory. .

Accordingly, when infrared rays are irradiated onto a tube into which a sample of a certain width is injected, the substance selectively absorbs light of a specific wavelength, and a specific chemical functional group specifically exhibits an infrared spectrum, which indicates an intrinsic wavelength region such as a human fingerprint. It can be estimated and usefully used for the qualitative determination of materials. Therefore, by selectively measuring the representative wavelength of the organic solvent it is possible to confirm the degree of contamination of the organic solvent to be used.

Therefore, the infrared spectroscopy device developed by the present invention is more economical than the conventional chemical analysis device, and can be repeatedly measured only at a selected wavelength.

In addition, the device of the present invention can be easily connected and controlled to the organic solvent management system because its configuration is simple.

In addition, the present invention can easily measure the salinity quantitatively by recognizing only a specific wavelength for each organic solvent.

In addition, when measuring the degree of contamination according to infrared spectroscopy, as shown in Figure 4, it can be seen that the new oil before use in the infrared spectrum of the organic solvent absorbs strong infrared rays at 505 cm ^-1 , the used oil after use is 499 cm ^-1 It can be seen from the absorption of strong infrared rays. Therefore, it can be seen that the absorption of 499 cm ⁻¹ is continuously increased according to the pollution degree.

Therefore, it is possible to create a database according to the functional groups of the various organic solvents, to selectively distinguish the various organic solvents.

As such, the present invention detects spectroscopic characteristics of the organic solvent using an infrared spectrometer and analyzes the detected data to determine the degree of reuse of the organic solvent by measuring the degree of contamination of the organic solvent in use.

As described above, the automatic classification device of the contaminated organic solvent and the method using the infrared spectrometer according to the present invention detects the spectroscopic characteristics of the organic solvent using an infrared spectrometer and analyzes the detected data. By measuring the degree of contamination of the organic solvent it is possible to determine whether or not to reuse the organic solvent.

In addition, the apparatus of the present invention has the advantage that it is economical compared to the conventional chemical analysis apparatus, and it is possible to measure repeatedly with only a selected wavelength in a small size.

In addition, the device of the present invention has a simple configuration, it is possible to easily connect and control the organic solvent management system.

Furthermore, the present invention can easily measure salinity quantitatively by recognizing only a specific wavelength for each organic solvent.

In addition, the present invention has an effect that can be selectively distinguished by creating a database according to the functional groups of various organic solvents.

Although the above has been described as being limited to the preferred embodiment of the present invention, the present invention is not limited thereto and various changes, modifications, and equivalents may be used. Therefore, the present invention can be applied by appropriately modifying the above embodiments, it will be obvious that such application also belongs to the scope of the present invention based on the technical idea described in the claims below.

Claims (11)

A constant pressure pump for supplying an organic solvent; A constant temperature chamber for chemically stabilizing the organic solvent supplied from the constant pressure pump; An infrared light source unit for irradiating an infrared light source; A continuous flow cell unit receiving the organic solvent stabilized in the constant temperature chamber and irradiating the organic solvent with the infrared light of the infrared light source unit; An optical separation unit separating the wavelength of the infrared light emitted from the continuous flow cell unit; And And a pollution degree classification unit for classifying a pollution degree of the organic solvent by detecting a spectrum of wavelengths of the light separated by the optical separation unit. The contamination classification unit may include: a detector configured to detect a spectrum of wavelengths of light separated by the optical separation unit; A signal control and amplifying unit for controlling and amplifying the signal detected by the detecting unit; An operation unit configured to perform an operation for classifying pollution degree on the signal amplified by the signal control and amplification unit; And a control and output unit for receiving the result calculated by the calculating unit to quantify the degree of contamination of the organic solvent and output the result. 2. The automatic classification apparatus of the contaminated organic solvent using the infrared spectrometer. A constant pressure pump for supplying an organic solvent; A constant temperature chamber for chemically stabilizing the organic solvent supplied from the constant pressure pump; An infrared light source unit for irradiating an infrared light source; A continuous flow cell unit receiving the organic solvent stabilized in the constant temperature chamber and irradiating the organic solvent with the infrared light of the infrared light source unit; An optical separation unit separating the wavelength of the infrared light emitted from the continuous flow cell unit; A pollution degree classification unit for classifying a pollution degree of the organic solvent by detecting a spectrum of wavelengths of light separated by the optical separation unit; And And an organic solvent management unit for managing the organic solvent according to the pollution degree of the organic solvent classified by the pollution degree sorting unit. The method according to claim 1, The automatic classification device of the contaminated organic solvent using the infrared spectrometer, An organic solvent manager configured to manage the organic solvent according to the pollution degree of the organic solvent classified by the pollution degree classification unit; Automatic classification device of the contaminated organic solvent using an infrared spectroscopy device further comprises. The method according to any one of claims 1 to 3, The constant pressure pump, Automatic sorting device of contaminated organic solvent using infrared spectroscopy, characterized in that to supply organic solvent including fresh oil or used oil. A constant pressure pump for supplying an organic solvent including fresh oil or used oil; A constant temperature chamber for chemically stabilizing the organic solvent supplied from the constant pressure pump; An infrared light source unit for irradiating an infrared light source; A continuous flow cell unit receiving the organic solvent stabilized in the constant temperature chamber and irradiating the organic solvent with the infrared light of the infrared light source unit; An optical separation unit separating the wavelength of the infrared light emitted from the continuous flow cell unit; A pollution degree classification unit for detecting a spectrum of wavelengths of the light separated by the optical separation unit to classify the pollution degree of the organic solvent; An organic solvent manager configured to manage the organic solvent according to the pollution degree of the organic solvent classified by the pollution degree classification unit; It is configured to include, The pollution degree classification unit, A detector for detecting a spectrum of the light separated by the optical separator; A signal control and amplifying unit for controlling and amplifying the signal detected by the detecting unit; An operation unit configured to perform an operation for classifying pollution degree on the signal amplified by the signal control and amplification unit; And a control and output unit which receives the result calculated by the calculating unit to quantify the contamination degree of the organic solvent and output the result. Automatic classification device of the contaminated organic solvent using an infrared spectroscopy device configured to include. A first step of injecting the organic solvent into a tube having a predetermined width and supplying the injected solvent at a constant pressure; A second step of irradiating the organic solvent with an infrared light source after the first step; And And a third step of detecting contamination of the organic solvent by detecting light irradiated after the second step. The first step is, An eleventh step of injecting an organic solvent into a tube having a predetermined width; A twelfth step of supplying the injected solvent at a constant pressure after the eleventh step; And a thirteenth step of chemically stabilizing the organic solvent in the constant temperature chamber after the twelfth step. The automatic classification method of the contaminated organic solvent using an infrared spectrometer. The method according to claim 6, In the first step, the organic solvent, Automatic classification method of contaminated organic solvent using infrared spectroscopy, characterized in that the new oil or used oil. delete The method according to claim 6, The third step, A twenty-first step of separating the light irradiated to the organic solvent after the second step; A twenty-second step of detecting a spectrum of wavelengths of light separated after the twenty-first step; And A twenty-third step of checking the pollution degree of the organic solvent by calculating the spectrum detected after the twenty-second step and outputting the result; Automatic classification method of contaminated organic solvents using an infrared spectroscopy device configured to include. The method according to any one of claims 6, 7 or 9, The automatic classification method of the contaminated organic solvent using the infrared spectrometer, A fourth step of managing the organic solvent according to the pollution degree of the organic solvent classified by the organic solvent manager after the third step; Automatic classification method of the contaminated organic solvent using an infrared spectroscopy device configured to further include. A thirty-first step of injecting an organic solvent including fresh oil or used oil into a tube having a predetermined width; A thirty-second step of supplying the solvent injected after the thirty-first step with a constant pressure; A thirty-third step of chemically stabilizing the organic solvent in the constant temperature chamber after the thirty-second step; A thirty-fourth step of irradiating the organic solvent with an infrared light source after the thirty-third step; A thirty-fifth step of separating the light irradiated to the organic solvent after the thirty-fourth step; A thirty-sixth step of detecting a spectrum of wavelengths of the light separated after the thirty-fifth step; A thirty-seventh step of checking the contamination level of the organic solvent by calculating the spectrum detected after the thirty-sixth step and outputting the result; And A 38 th step of managing the organic solvent according to the pollution degree of the organic solvent classified by the organic solvent manager after the 37 th step; Automatic classification method of the contaminated organic solvent using an infrared spectroscopy device configured to include.

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