KR101108544B1 - Non-dispersive Infrared Gas Analyzer - Google Patents

Abstract

The non-dispersion infrared gas measuring apparatus according to the present invention is a non-dispersion infrared gas measuring apparatus, which constitutes an outer portion of the non-dispersing infrared gas measuring apparatus, and provides an optical waveguide for providing a path through which infrared rays can absorb an gas. 240; An infrared lamp (210) positioned inside the optical waveguide to emit the infrared light; A reflector plate 220 positioned behind the infrared lamp to radiate the infrared rays forward; An optical sensor 230 that detects infrared rays arriving at the optical waveguide without being absorbed by the gas and converts the infrared rays into electrical signals; And a controller 250 disposed in a space in which the optical waveguide is installed and remaining, and controlling the infrared lamp and extracting a concentration of the gas from the electrical signal, and an area 260 in contact with the outside of the space where the controller is installed. A first air inlet (261) is formed in a portion of the () to the air inlet, the second air inlet (241, 242) is formed in a portion of the area where the control unit and the optical waveguide abuts, the area abuts the outside of the optical waveguide It is characterized in that the inlet and outlet of the air is smoothly formed by forming an air outlet 243 in some of.

Gas, infrared, non-dispersion

Description

Non-dispersive Infrared Gas Analyzer

The present invention relates to a non-dispersion infrared gas measurement device, and more particularly, to a non-dispersion infrared gas measurement device having a fast reaction rate by smoothly flowing air.

Infrared refers to electromagnetic waves that have a wavelength longer than visible light and fall in the range of 0.75 micrometers (µm) to 1 millimeter (mm) or less, of which wavelengths from 0.75 micrometers (µm) to 2.5 micrometers (µm) are near infrared, Medium micrometers (μm) to 25 micrometers (μm) are called medium (infrared) infrared rays, and more than 25 micrometers (μm) are called far infrared rays, which are called heat rays because they emit heat that is stronger than visible or ultraviolet light. Pray.

Infrared rays have such a strong thermal effect because the frequency of the infrared rays is about the same as the natural frequency of the molecules that make up the substance, which causes electromagnetic resonance when the substance hits the substance, resulting in light waves energy. It is known that is effectively absorbed.

In particular, liquid or gaseous substances have the property of strongly absorbing infrared rays of specific wavelengths, and thus the absorption spectrum is used to accurately estimate the chemical composition, reaction process or molecular structure of the substance. This is called infrared spectroscopic analysis.

There is a non-dispersive infrared gas measuring device as a quantitative analysis device which analyzes the concentration of a specific gas in a sample using such infrared characteristics.

1A and 1B illustrate an embodiment of a non-dispersion infrared gas measuring apparatus according to the prior art.

The non-dispersion infrared gas measuring apparatus shown in Figure 1a and 1b is an infrared lamp 120 for emitting infrared light, an optical sensor 140 for detecting the infrared light not absorbed by the optical waveguide 130 and converting it into an electrical signal, The infrared light emitted from the infrared lamp 11 is provided with an optical waveguide 130, which can cause an absorption reaction to the gas, and a reflector 131 located at the bent portion to transfer light well. The optical waveguide 130 is extended from the infrared lamp 120 to the optical sensor 140 to secure an infrared path.

In the non-dispersion infrared gas measuring apparatus, in order to improve gas detection characteristics, a distance from the infrared lamp 120 to the optical sensor 140 is long, and a structure for easily transmitting light is required. Smooth air flow is very important.

That is, when the distance of the optical waveguide 130 is long, the change of the output of the gas measuring device is large due to the change in the amount of gas, so that the detection characteristic is generally good. In addition, the gas measuring device should have a structure in which external air is easily introduced into and exited from the optical waveguide 130 in order to accurately measure it as soon as possible.

The upper and lower air passages 151 are formed to improve the flow of air, and the side air passages 132 are formed to inject air into the optical waveguide 130. However, although the non-dispersion infrared gas measuring apparatus shown in FIGS. 1A and 1B has a passage through which air flows from the outside to the optical waveguide, there is no passage through which air flows directly from the optical waveguide to the outside, so that the inflow and outflow of air is not smooth. There is a problem.

The technical problem to be achieved by the present invention is to provide a non-dispersive infrared gas measurement device having a fast reaction rate by providing a smooth air circulation by providing an air outlet.

The non-dispersion infrared gas measuring device according to the present invention for achieving the above technical problem comprises a non-dispersion infrared gas measuring device, which constitutes the outer periphery of the non-dispersing infrared gas measuring device, the infrared rays can cause an absorption reaction to the gas An optical waveguide 240 providing a passageway; An infrared lamp (210) positioned inside the optical waveguide to emit the infrared light; A reflector plate 220 positioned behind the infrared lamp to radiate the infrared rays forward; An optical sensor 230 that detects infrared rays arriving at the optical waveguide without being absorbed by the gas and converts the infrared rays into electrical signals; And a controller 250 disposed in a space in which the optical waveguide is installed and remaining, and controlling the infrared lamp and extracting a concentration of the gas from the electrical signal, and an area 260 in contact with the outside of the space in which the controller is installed. A first air inlet (261) is formed in a portion of the () to the air inlet, the second air inlet (241, 242) is formed in a portion of the area where the control unit and the optical waveguide abuts, the area abuts the outside of the optical waveguide It is characterized in that the inlet and outlet of the air is smoothly formed by forming an air outlet 243 in some of.

The non-dispersion infrared gas measuring device according to the present invention has an effect that the reaction speed is fast and accurate by reducing the circulation of air, and the device area is reduced.

Hereinafter, with reference to the accompanying drawings to describe the present invention in more detail.

2 shows an embodiment of a non-dispersion infrared gas measuring apparatus 200 according to the present invention.

The non-dispersion infrared gas measuring apparatus 200 illustrated in FIG. 2 includes an infrared lamp 210, an optical waveguide 240, an optical sensor 230, a reflector 220, and a controller 250.

The infrared lamp 210 is provided on one side of the optical waveguide 240 to emit infrared light.

The infrared lamp 210 uses one having a wavelength of light absorbed by the gas to be measured.

The reflecting plate 220 is provided at the end of the infrared lamp side in the optical waveguide, and is configured to reflect the light emitted from the infrared lamp 210 to the optical waveguide 240 to the maximum.

 The optical waveguide 240 is preferably configured so that external light is not allowed to enter outside the light emitted from the infrared lamp 210.

The curved portion of the optical waveguide is curved so that as much infrared light as possible goes toward the optical sensor 230. Therefore, by forming various bends between the infrared lamp and the optical sensor, it is possible to increase the efficiency of light reflection.

In addition, the non-dispersion infrared gas measuring apparatus according to the present invention may further include a reflector (not shown) provided on the wall surface of the bend so that the infrared ray may proceed toward the optical sensor.

The optical waveguide may be formed in a multi-stage bent structure, and in FIG. 2, the optical waveguide is bent in two stages and has a 'c' shape. Therefore, the optical waveguide 240 has a structure that forms three of four surfaces of the outer side of the gas measuring device.

The optical waveguide 240 serves as an optical path through which the emitted infrared rays pass through while being partially absorbed until they reach the optical sensor, and the longer the path through which the infrared rays pass through, the greater the amount of absorption by the gas, and thus the final measured value. The accuracy of the instrument can be increased by reducing the error of.

The optical sensor 230 is provided on the side opposite to the side where the infrared lamp is located in the optical waveguide, and detects infrared rays not absorbed by the gas in the optical waveguide 240 and converts them into an electrical signal.

The controller 250 is configured to adjust the light intensity of the infrared lamp 210 and extract the concentration of the gas from the electrical signal of the light sensor 230.

In order to minimize the overall size of the infrared gas measuring apparatus according to the present invention, the portion not used as the optical waveguide is used as a space in which electronic components such as the controller 250 are installed.

The controller 250 may be disposed in a space surrounded by one surface of the outside of the gas measuring device 200 and the surfaces contacted with the optical waveguide to minimize the overall device area.

The infrared radiation emitted from the infrared lamp travels along the optical waveguide and is absorbed by the gas in the air, and the unabsorbed infrared light is converted into an electrical signal by the optical sensor.

In particular, the non-dispersion infrared gas measuring apparatus according to the present invention forms a first air inlet 261 as a passage of the air containing the gas so that the air is introduced into a part of the area in contact with the outside of the space in which the control unit is installed, Second air inlets 241 and 242 are formed in a portion of the region where the control unit and the optical waveguide are in contact with each other, and an air outlet 243 is formed in a portion of the region where the optical waveguide 240 is in contact with the outside to smoothly flow the air. It is possible to measure the concentration of gas in the air quickly and accurately. That is, the non-dispersion infrared gas measuring apparatus according to the present invention is provided with an air inlet for the inlet and outlet of the air in the optical waveguide, it has a structure that can smoothly flow the air.

The size of the air inlet and the second air inlet of the first air inlet and the optical waveguide of the control unit shown in FIG. 2 is different from the actual ratio and is largely illustrated to show that there is air flow.

In addition, the non-dispersion infrared gas measuring apparatus according to the present invention further comprises a fan (not shown) for forced ventilation on the outside of the first air inlet 261 or the outside of the air outlet 243, the flow of air To make it more smooth.

Alternatively, the control unit 250 may include a fan to inject air through the first air inlet 261 to smoothly flow the air.

The operation of the non-dispersion infrared gas measuring apparatus according to the present invention will be described with reference to FIG.

First, when the infrared lamp 210 is turned on, infrared rays emitted from the infrared lamp 210 may be reflected toward the front through the reflector 220 disposed behind the infrared lamp 210. The infrared rays may pass through all of the optical waveguides 240 that are bent in multiple stages forward through reflecting mirrors (not shown) positioned at corners of the optical waveguides 240, and some of the infrared rays may be provided in the first air inlets 261. In addition, the infrared rays absorbed by the gas introduced through the second air inlets 241 and 242 and the air outlet 243 are not absorbed and are converted into electrical signals by the optical sensor 230.

Figure 3 shows an air flow diagram of the infrared gas measurement apparatus according to the present invention.

Outside air is introduced into the installation space of the controller 250 through the first air inlet 261 at the bottom of the infrared gas measuring device 200. At this time, the air is expanded by the heat generated from the electronic components constituting the controller 250 and rapidly flows into the optical waveguide 240 through the second air inlets 241 and 242 formed on the left and right sides thereof. The air entering the optical waveguide 240 rises up by the heat generated by the infrared lamp 210 and the optical sensor 230, and the raised air passes out through the air outlet 243 formed above the optical waveguide. do. Therefore, the air flows smoothly, so that the gas contained in the air can be quickly detected.

The air outlet 243 may be formed at an upper portion of the outer partition wall or the upper front surface of the outer waveguide 240. That is, the air outlet 243 is formed on the opposite side of the first air inlet to facilitate the inflow and outflow of air.

The present invention facilitates the flow of air by properly arranging the air inlet and the air outlet even with a smaller number of air passages than the non-dispersing infrared gas measuring apparatus according to the prior art, thereby increasing the concentration of the gas contained in the outside air. When it is changed, it can be detected in a short time, and since the number of air passages is small, it is advantageous to increase the accuracy of gas measurement by being less affected by external light.

As a light source of an infrared lamp, tungsten, a glover, a nernst glover, a high-pressure mercury lamp for infrared rays, or an infrared laser is used.

The technical spirit of the present invention has been described above with reference to the accompanying drawings, but the present invention has been described by way of example and is not intended to limit the present invention. In addition, it is obvious that any person skilled in the art to which the present invention pertains can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

1A and 1B illustrate an embodiment of a non-dispersion infrared gas measuring apparatus according to the prior art.

Figure 2 shows an embodiment of a non-dispersion infrared gas measuring apparatus according to the present invention.

Figure 3 shows an air flow diagram of the non-dispersion infrared gas measurement device according to the present invention.

Claims (8)

In the non-dispersion infrared gas measuring device, An optical waveguide 240 constituting an outer portion of the non-dispersion infrared gas measuring device, the optical waveguide 240 providing a passage through which infrared rays may cause an absorption reaction to the gas; An infrared lamp (210) positioned inside the optical waveguide to emit the infrared light; A reflector plate 220 positioned behind the infrared lamp to radiate the infrared rays forward; An optical sensor 230 that detects infrared rays arriving at the optical waveguide without being absorbed by the gas and converts the infrared rays into electrical signals; And The optical waveguide is installed and disposed in the remaining space, the control unit 250 for adjusting the intensity of the light of the infrared lamp and extracting the concentration of the gas from the electrical signal, A first air inlet 261 is formed at a lower end of an area 260 in contact with the outside of the space where the control unit is installed, and a second air is formed in a part of an area where the control unit and the optical waveguide are in contact with each other. Non-dispersive infrared rays characterized in that the inlet (241,242) is formed, and the air inlet (243) is formed on the upper end of the region opposite to the air inlet of the area in contact with the outside of the optical waveguide, the inflow and outflow of air smoothly. Gas measuring device. The method of claim 1, The optical waveguide (240) is a non-dispersion infrared gas measurement device, characterized in that the multi-stage bending structure. 3. The method of claim 2, The optical waveguide 240 is bent in two stages to form three of the four sides of the outer periphery of the gas measuring device, characterized in that the non-dispersion infrared gas measuring device. The method of claim 3, The control unit 250 is a non-dispersion infrared gas measurement device, characterized in that disposed in the space surrounded by one surface of the outer surface of the gas measuring device and the surface in contact with the optical waveguide. delete The method of claim 3, Non-dispersion infrared gas measuring device further comprises a reflector provided on the wall surface is bent so that the infrared ray can proceed toward the optical sensor. The method of claim 1, The control unit, And a fan for forcibly injecting air through the first air inlet. The method of claim 1, Non-dispersion infrared gas measurement device further comprises a fan for forced ventilation outside the first air inlet or the outside of the air outlet.

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