KR102640750B1 - A device for detecting a gas mixture of hazardous substances using a bandpass filter - Google Patents

Abstract

The present invention relates to a device for detecting mixed gases of hazardous substances using a band-pass filter, and more specifically, to a small-sized detection device that applies a band-pass filter method to easily detect hazardous gases in the atmosphere where various substances are mixed. will be. This device includes a laser light source unit 10, a sensor substrate 20, a reflection mirror 60, a spectroscopic unit 30, and a light detection unit 40.

Description

A device for detecting a gas mixture of hazardous substances using a bandpass filter}

The present invention relates to a device for detecting mixed gases of harmful substances using a bandpass filter (BPF). More specifically, in order to easily detect harmful gases in the atmosphere mixed with various substances, a bandpass filter method is used. It relates to a small detection device applied.

Many types of dangerous gases exist in our living environment, and recently, gas accidents at homes, businesses, and construction sites, explosion accidents, and pollution at oil complexes, coal mines, and chemical plants have been occurring one after another.

Since human sense organs cannot quantify the concentration of dangerous gases or determine the type, gas sensors using the physical and chemical properties of substances have been developed to respond to this, detecting gas leaks, measuring and recording concentrations, and providing alarms. It is used, etc.

In particular, as ventilation is insufficient in closed indoor spaces, the need to accurately detect harmful gases such as toluene and formaldehyde early and block their spread is increasing. However, environmental monitoring that can specifically detect or select various types of gases is increasing. The system is lacking.

Accordingly, Raman spectroscopy is a method of performing both qualitative and quantitative analysis of each material by measuring the material's unique vibration spectrum and finding the material's unique spectrum, and is used to detect gases as described above.

However, conventional Raman spectroscopy had the problem of low signal intensity and low sensitivity. To solve this problem, a new surface-enhanced Raman spectroscopy (SERS) detection method was recently developed that amplifies the Raman spectrum of chemicals bound or adsorbed on the surface of metal nanoparticles (see Patent Document 1).

The Raman measurement method has the advantages of very high sensitivity (detection limit: tens of ppb), recognition of molecular structure, portability, and short measurement time (within a few seconds).

Meanwhile, spectroscopy has recently been applied to the observation and analysis of air pollutants and hazardous substances. In general, spectroscopy is the study of the interaction between electromagnetic radiation and various samples (e.g., containing one or more of gases, solids, and liquids). How radiation reacts with a particular sample depends on the sample's properties (e.g., molecular composition).

Generally, as radiation passes through a sample, certain wavelengths of radiation are absorbed by molecules within the sample. The specific wavelength of radiation absorbed is specific to each molecule in a particular sample. By identifying which wavelengths of radiation are absorbed, it is possible to identify specific molecules present within a sample. For example, in the infrared absorption method, since gases have different unique absorption spectra, it is possible to selectively measure only specific gases by using a band-pass filter that matches the absorption spectrum of the measured gas.

However, modification of the surface of nanoparticles as described above is very difficult and expensive, so no technology has yet been attempted to detect hazardous gases in the atmosphere where various substances are mixed. In addition, optical sensors using Raman scattering have the disadvantage of being large in size and relatively expensive because the optical system for signal transmission is complex.

To improve this, a measurement system with a new spectrometer is required.

Domestic registered patent No. 10-1942911 (registration date 2019.01.22.) Domestic Published Patent No. 10-2011-022099 (publication date 2011.03.07.) Domestic Published Patent No. 10-2013-0081843 (publication date 2013.07.18.) Japanese Patent Publication No. 3866231 (registration date 2006.10.13.)

The present invention was devised to solve the above-mentioned problem, and the purpose of the present invention is to provide a detection device that can easily detect a number of harmful gases mixed in indoor air using a spectroscopic system including a band-pass filter. .

Another object of the present invention is to provide a detection device that is inexpensive to install and cost-effective and can construct an optical system with a compact structure.

In order to solve the above-described problem, an apparatus for detecting mixed gases of hazardous substances for improving indoor air quality using a band-pass filter according to an embodiment of the present invention includes a laser light source unit 10 that generates laser light; A sensor substrate (20) that irradiates the generated laser light to the mixed gas particles to be analyzed and transmits an optical signal scattered therefrom in a Raman manner; The optical signal scattered from the sensor substrate is reflected through a reflection mirror 60 and transmitted through a bandpass filter 50 with n specific frequency bands; a spectrometer 30; and a light detection unit 40 that detects the optical signal transmitted from the spectrometer.

The n specific frequency bands have a slit or circular shape.

The band-pass filter is characterized in that it selectively blocks or transmits specific wavelengths while being moved left and right using a sliding adjustment means.

The sensor substrate is characterized by using a surface-enhanced Raman scattering method in which metal nanoparticles coated with 1-propanethiol are coated on the surface.

A detection method for measuring the hazardous substance mixed gas using a detection device is provided.

According to the present invention, by using a spectroscopic system including a band-pass filter, it is possible to not only measure a single gas but also easily detect mixed gases of multiple hazardous substances by separating them by wavelength, and only one band-pass filter can replace several dedicated filters. This makes equipment and production costs low.

In addition, according to the present invention, individual detection is possible through Raman signals regardless of the type of gas, so there is no need to manufacture several types of sensors, which lowers the unit cost of the product and makes it easy to miniaturize.

Figure 1 is a schematic diagram of a device for detecting mixed gases of hazardous substances using a band-pass filter according to an embodiment of the present invention.
Figure 2 is a diagram of a band-pass filter of various shapes according to the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the attached drawings. However, in describing the embodiments, if it is determined that specific descriptions of related known functions or configurations may unnecessarily obscure the gist of the present invention, detailed descriptions thereof will be omitted. Additionally, the size of each component in the drawings may be exaggerated for explanation and does not mean the actual size.

The device for detecting mixed gases of hazardous substances using a band-pass filter according to the present invention includes a laser light source unit 10, a sensor substrate 20, a reflection mirror 60, a spectrometer 30, and a light detection unit 40. It is composed. Figure 1 is a schematic diagram of a device for detecting mixed gases of hazardous substances using a band-pass filter according to an embodiment of the present invention.

The laser light source unit 10 is configured to oscillate laser light irradiated to mixed gas particles, which are analytes adsorbed on the sensor substrate. In the present invention, the light source unit 10 is preferably constructed simply by using a laser diode.

The sensor substrate 20 is configured to irradiate laser light to the mixed gas particles to be analyzed and obtain optical signals scattered by the Raman method from the gas particles, and 1-propanethiol is added to the surface of the metal nanoparticles of the substrate. Surface-enhanced Raman scattering (SERS) is used to facilitate the detection of harmful gases mixed in the air by coating. For detailed information about this, please refer to the present inventor's domestically registered patent No. 10-1942911.

The Raman measurement method above is a method of obtaining a scattered light signal whose energy is changed due to the interaction between light energy generated when a laser light source of a specific wavelength is irradiated to a sample and molecular vibration. Because unique vibration modes exist depending on the material, information about all organic and inorganic molecules can potentially be obtained.

Therefore, individual detection is possible through Raman signals regardless of the type of material (or gas), so there is no need to manufacture several types of sensors. In addition, since there are no restrictions on the light source, various light sources can be used, and the unit cost of the product can be lowered by using a relatively inexpensive laser light source in the wavelength range.

In addition, it is easy to miniaturize because it is a method of obtaining Raman information of the material present in the area where the laser beam is irradiated. In particular, when using a surface-enhanced Raman method such as the present invention, a signal stronger than the existing Raman signal can be obtained, and when the light source is ^freely changed, it is possible to manufacture an ultra-high sensitivity sensor for a specific gas using a specific light source. .

The spectrometer 30 is configured to separate and analyze Raman scattered optical signals emitted from the analyte. A band-pass filter through which light is transmitted according to the wavelength (or frequency band) is placed in the spectrometer, and the position of the filter is moved left and right using a sliding adjustment means such as a motor to select and control a specific band.

In other words, since one bandpass filter can replace several dedicated filters, system installation can be simplified and weight minimized for optical value.

In general, a bandpass filter refers to a filter that passes only signals in a specific frequency band without attenuation, and attenuates or blocks signals in other frequency bands. In other words, it is a filter that allows only the mid-frequency band of the incoming frequency to pass, and when the entire frequency passes through the band pass filter, only the mid-band passes, and the remaining low- and high-frequency bands are removed from the filter and output. For reference, frequency and wavelength are reciprocal or inversely proportional to each other. As the frequency increases, the wavelength shortens, and as the wavelength increases, the frequency decreases.

Figure 2 is a diagram of a planar bandpass filter with a specific frequency range of various shapes according to the present invention. (1) is about a filter with a specific frequency band in the shape of five slits, (2) is about a filter with a specific frequency band in the shape of five circles, and (3) is a filter that combines the shape of a slit and a circle. It's about filters.

In order for the scattered optical signal to pass (or be transmitted) divided by wavelength, a bandpass filter with n specific frequency bands is required. It must be composed of multiple frequency bands so that waves of different bands can pass through.

However, in terms of installation space and cost, the number of frequency bands (n) is 4 to 5, and the shape of the frequency band is preferably slit or circular, but is not particularly limited thereto. The design of the bandpass filter can be determined depending on the object to be measured. For example, you can configure a planar band-pass filter with five corresponding frequency bands so that light in the 450nm, 535nm, 570nm, 590nm, and 610nm wavelength bands can be transmitted.

Since specific wavelengths (or frequencies) are selectively blocked or transmitted depending on the wavelength of the optical signal scattered by the Raman method from the analyte, the optimal number or shape can be determined accordingly.

Using the above principles, a new spectrometer using a specific wavelength that can identify specific molecules present in a specific sample (harmful gas) was designed.

The optical detection unit 40 is configured to detect an optical signal transmitted from the bandpass filter of the spectrometer.

The photodetector may be a device that converts light into an electrical signal. The photodetector may be a silicon photodiode, a gimanium photodiode, or an InGaAs photodiode depending on the band to be measured. In some cases, CCD or PMT can also be used.

In the present invention, the process by which the above-described scattered light signal is transmitted from the spectrometer to the light detection unit will be looked at in more detail as follows.

The optical signal scattered from the sensor substrate can selectively pass a specific wavelength while the bandpass filter of the spectrometer moves its position, so the corresponding signals are continuously sent to the light detection unit.

First, it is necessary to conduct a basic investigation on the target substance (hazardous gas) to be analyzed or detected (see Domestic Patent No. 10-1942911). Then, since the surface-enhanced Raman scattered light signal for the specific gas component is determined, the specific gas can be compared and judged using the value measured by the photodetector after passing through a band-pass filter in a specific wavelength range. The measured value at this time may be a simple numerical value, but may also be in the form of a spectrum.

Specific examples of the gases may include gases volatilized from harmful substances such as toluene, benzene, dichlorobenzene, vinyl chloride, and carbon tetrachloride.

In other words, even if multiple harmful gases are mixed, they can be easily measured with a photodetector using the principle of transmitting or absorbing the wavelength range for the gas. Furthermore, depending on the photodetector being measured, qualitative as well as quantitative analysis may be possible.

Therefore, if you use the detection device that introduces a new spectroscope using a specific wavelength that can identify specific molecules present in a specific sample, even in an indoor space where a large number of mixed gases exist, you can analyze the components of harmful mixed gases. Real-time detection of gas diffusion is easily possible and can also be useful for monitoring polluting gases.

For reference, various modifications are possible without departing from the scope of the present invention. The technical idea of the present invention should not be limited to the above-described embodiments of the present invention, but should be determined not only by the claims but also by equivalents to the claims.

10: Laser light source unit
20: Sensor board
30: spectrometer
40: Light detection unit
50: Bandpass filter (BPF)
60: Reflection mirror

Claims (5)

A laser light source unit 10 that generates laser light;
A sensor substrate (20) that irradiates the generated laser light to the mixed gas particles to be analyzed and transmits an optical signal scattered therefrom in a Raman manner;
The optical signal scattered from the sensor substrate is reflected through a reflection mirror 60 and transmitted through a planar bandpass filter 50 with five specific frequency bands; a spectrometer 30; and
It includes a light detection unit 40 that detects the optical signal transmitted from the spectrometer,
The shape of the five specific frequency bands is characterized in that it is circular,
The bandpass filter is characterized in that specific wavelengths are selectively blocked or transmitted while being moved left and right using a sliding adjustment means,
A device for detecting mixed gases of hazardous substances for improving indoor air quality, characterized in that the sensor substrate uses a surface-enhanced Raman scattering method in which metal nanoparticles coated with 1-propanethiol are coated on the surface. delete delete delete delete