KR100232166B1 - Co2 gas detector - Google Patents

Abstract

A carbon dioxide gas detector, comprising: a compound semiconductor infrared light emitting diode or laser diode that emits infrared light having a wavelength of a carbon dioxide absorption band, an optical bench where infrared light is absorbed by carbon dioxide, and a change in absorption rate of infrared light in the optical bench By controlling the thermopile unit, the compound semiconductor infrared diode and the thermopile unit, and configuring the circuit unit and the output unit for signal output according to the carbon dioxide gas concentration, it is possible to reduce the size, cost, and complexity of the existing detector, thereby making it cheaper and smaller. Do it.

Description

Carbon dioxide gas detector

The present invention relates to a gas detector, and more particularly to a carbon dioxide gas detector.

Due to the increase in energy consumption due to industrialization, the demand for small and low-cost carbon dioxide detectors is increased in the current situation where the emission of carbon dioxide gas in the atmosphere is rapidly increased and the control of carbon dioxide gas content in the indoor air of buildings or living spaces is required. It is becoming.

However, carbon dioxide has a relatively stable binding property unlike many other gas types, and thus, there is a limit in detecting carbon dioxide using a conventional gas sensor method.

Therefore, in general, a non-dispersive infrared method (NDIR method) has been used so far to measure carbon dioxide gas.

Carbon dioxide gas detection principle and a conventional carbon dioxide detector according to the conventional non-dispersion infrared method is briefly described as follows.

Gas molecules composed of two or more different atoms, such as CO gas or CO ₂ gas, have the property of absorbing infrared rays at specific wavelengths depending on the chemical bonds, atomic weight, and molecular vibration of the gas molecules.

The absorption spectrum is used to determine the type of molecules at the absorption wavelength and to measure the concentration by the intensity of the absorption peak.

There are several absorption wavelength bands for each gas, but mainly CO ₂ is 4.24 μm, CO is 4.64 μm, and HC is 3.4 μm.

In general, when infrared light passes through a gas, the transmittance (100-absorbance) follows the Beer-Lambert law.

T = exp (-acl)

Where T is the transmittance, a is the constant due to the wavelength and gas molecules of light, c is the gas concentration, and l is the path length of light.

In other words, the higher the concentration of gas, the exponentially decrease in light transmittance.

In order to measure gas based on this basic principle, an infrared source capable of emitting infrared rays of a specific wavelength band, a filter that passes only light of a specific wavelength, and an infrared detector capable of measuring infrared rays changed by a gas It consists of an optical bench, a space in which infrared light from an infrared source is absorbed by a gas at a suitable length, the structure of which is shown in FIG.

As shown in FIG. 1, the carbon dioxide detector is configured in the form of various components mounted in a mechanically configured optical bench.

First, the infrared source generates heat when a current is applied in a thermal manner, and infrared rays of a wide wavelength band of 10 μm or more are radiated from the corresponding 1 μm or less.

These sources are power hungry, must be sealed with inert gas when used in explosive atmospheres, are susceptible to vibration and shock, and change in slope over time, which must be taken into account in system design.

In addition, the photodiode is separately attached for constant adjustment of the infrared radiation amount, and the design of the heat dissipation structure prevents malfunction due to heat generated from the source.

In addition, when a quantum infrared detector or a pyroelectric infrared detector is used as an infrared detector, a chopping shutter is mainly used as a subsidiary device that controls the light at a specific frequency to perform a detector function.

The addition of a motor and driving circuit for driving such a chopping shutter makes it difficult to increase the price, maintain and repair, make it difficult to miniaturize, and complicate the whole system.

Infrared light from the light source passes through the lens into the optical bench where it is absorbed by carbon dioxide.

In general, optical benches are processed by mechanical methods, which are large and complex, with several tens of centimeters in length.

1 is a compensation structure for other environmental variables (temperature, flow, humidity, etc.) in addition to the measurement gas.

The infrared rays absorbed by the gas and the remaining transmitted infrared rays are used to enter the detector as shown in the right end of FIG.

In this case, the infrared light passing through the lens passes a narrow band infrared filter and sends only a wavelength of a specific band to the detector.

This is because the CO ₂ gas absorbs only 4.24 μm (± 0.05 μm) wavelength.

This infrared filter is mainly attached to the package of the detector.

Infrared detectors currently use quantum type or pyroelectric infrared detectors, which have excellent sensitivity to infrared rays, but in the case of quantum type, a chopping shutter and a cooler that cools them to a low temperature are required. It has the disadvantages of complexity, large size and high price.

In FIG. 1, a cooler composed of a thermoelectric element is mounted to cool the quantum infrared detector, and a separate circuit and a system for driving the quantum infrared detector are required.

The carbon dioxide gas detector according to the prior art has the following problems.

Conventional detectors are complex, large and expensive in structure.

The present invention has been made to solve such a problem, and an object thereof is to provide a carbon dioxide gas detector having a simple structure, a low cost, and a small size.

1 shows a carbon dioxide gas detector according to the prior art.

2 is a block diagram showing a carbon dioxide gas detector according to the present invention.

3 is a graph showing infrared radiation characteristics of a light emitting diode of a carbon dioxide gas detector according to the present invention.

4 shows an optical bench of a carbon dioxide gas detector according to the present invention.

5 is a graph showing the output characteristics according to the carbon dioxide concentration of the carbon dioxide gas detector according to the present invention.

* Explanation of symbols for main parts of the drawings

11 light emitting diode or laser diode 12 optical bench

13: thermopile section 14: circuit section

15: output unit

The characteristic of the carbon dioxide gas detector according to the present invention is that a compound semiconductor infrared light emitting diode or a laser diode emitting infrared rays having a wavelength of carbon dioxide absorption band, an optical bench where infrared rays are absorbed by carbon dioxide, and a change in absorption rate of infrared rays in the optical bench It consists of a thermopile unit for detecting the, and a circuit unit for controlling the compound semiconductor infrared diode and the thermopile unit and outputs a signal according to the carbon dioxide gas concentration.

Referring to the carbon dioxide gas detector according to the present invention having the features as described above with reference to the accompanying drawings as follows.

First, the concept of the present invention is to produce a carbon dioxide gas detector to enable a low cost, small size by improving the complexity of the large size, high price, and the system known to various disadvantages of the conventional non-dispersion infrared detector.

FIG. 2 is a block diagram showing a carbon dioxide gas detector according to the present invention. As shown in FIG. 2, a compound semiconductor infrared light emitting diode or a laser diode 11 having a carbon dioxide absorption band emitting infrared rays having a wavelength and The optical bench 12 in which infrared rays are absorbed by carbon dioxide, the thermopile portion 13 for detecting a change in the absorption rate of infrared rays from the optical bench 12, the compound semiconductor infrared light emitting diode or laser diode 11, and It consists of a circuit part 14 and an output part 15 for controlling the thermopile part 13 and obtaining a signal output according to the carbon dioxide gas concentration.

As shown in FIG. 2, the present invention does not require a chopping shutter and a cooler, unlike a conventional detector, and thus can be miniaturized and reduced in price.

First, the infrared source uses a compound semiconductor infrared light emitting diode rather than a thermal method to output a narrow band of infrared light at a constant value around 4.25 μm where absorption is caused by carbon dioxide gas rather than broadband.

Here, a laser diode may be used instead of the light emitting diode.

The light emitting diode used in the present invention uses a GaSb-InAs compound semiconductor to supply current to both electrodes of the light emitting diode to control the intensity of infrared radiation.

3 is a graph showing the infrared radiation characteristics of the light emitting diodes used in the present invention in the presence of a small amount of carbon dioxide. As shown in FIG. 3, infrared light is absorbed in a relatively narrow band around 4.25 μm by carbon dioxide. Able to know.

When using a light emitting diode or a laser diode, it can be miniaturized, fast response, electrical chopping, low power consumption, and high power.

In addition, although the optical bench is composed of a light path in a straight line in a conventional detector, the present invention enables miniaturization by allowing an infrared path length of a predetermined length or more to come out in a small space by using various reflecting mirrors.

As shown in FIG. 4, MEMS technology, semiconductor processing technology, and etching technology are used to construct an optical bench to lengthen the optical path length even in a narrow space, thereby facilitating carbon dioxide gas detection.

That is, the infrared rays emitted from the light source (light emitting diode or laser diode) are reflected by each other by the micro reflector and then incident on the infrared detector.

In addition, the replacement of conventional quantum infrared detectors with chopping shutters and coolers with thermopile infrared detectors enables simple carbon dioxide detectors without the need for auxiliary functional components.

In addition, the thermopile infrared detector has a relatively simple driving circuit.

5 is a graph showing the output characteristics according to the carbon dioxide concentration of the carbon dioxide gas detector according to the present invention, as shown in Figure 5, it can be seen that excellent detection characteristics for the carbon dioxide gas.

As described above, the carbon dioxide gas detector of the present invention is simple in structure, low in cost, and small in size.

The carbon dioxide gas detector according to the present invention has the following effects.

The infrared source of the present invention uses a compound semiconductor infrared light emitting diode rather than the conventional thermal method, so that a narrow band of infrared rays around 4.25 μm, which is absorbed by carbon dioxide gas rather than broadband, is output at a constant value, thereby miniaturizing and responding quickly. It has enabled sex, electrical chopping, low power consumption, and high power, and by replacing the existing quantum infrared detector with a thermopile infrared detector that requires a chopping shutter and cooler, a simple carbon dioxide detector without the need for auxiliary function components is possible. It was.

In addition, although the conventional detector is configured to form an optical path in a straight line in the optical bench (in the present invention) by using a variety of reflectors in the small space by allowing the infrared path length of a predetermined length or more to come out to be miniaturized.

Claims (3)

An infrared diode emitting infrared rays having a wavelength of a carbon dioxide absorption band; An optical bench in which the infrared rays are absorbed by carbon dioxide; A thermopile unit for detecting a change in absorbance of infrared rays in the optical bench; Carbon dioxide gas detector, characterized in that consisting of a circuit portion for controlling the compound semiconductor infrared diode and the thermopile section and outputs a signal according to the carbon dioxide gas concentration. The carbon dioxide gas detector of claim 1, wherein the infrared diode is a compound semiconductor light emitting diode or a laser diode. The carbon dioxide gas detector of claim 1, wherein the optical bench is arranged with reflectors to reflect infrared rays emitted from the infrared diodes into the reflector and to enter the infrared detector.

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