KR20220008451A - Improved chimney dust gauge - Google Patents

Abstract

In the case of a conventional dust measurement device, the light intensity of a light source may be changed through continuous measuring. A difference in measurement results caused by dust onto a front protection window that separates a chimney and a chimney dust measurement device of the present invention has been calibrated using a reflector. However, it is not known whether the calibration is caused due to a change in the light intensity of the light source or caused due to the fact that the front protection window is dirty, and there is a problem in that it is necessary to separately check the replacement timing and defects of the light source. In order to solve these problems, an improved chimney dust measurement device is provided. The improved chimney dust measurement device comprises: a light source; a half mirror through which light emitted from the light source passes; a reflector which reflects, in a 180 degree direction, light after the light that has passed through the half mirror sequentially passes through a rotation filter LINK2 and a rotation filter LINK1 and a chimney; and a transmitted light photo detector which measures the amount of light after the light that has passed through the reflector passes through the rotation filter LINK2 and the rotation filter LINK1 in reverse order and then rotates 90 degrees through the half mirror so that dust included in exhaust gas of the chimney is measured. The present invention has the effect of conveniently and efficiently calibrating the chimney dust measurement device and aligning the optical axis by the above-described problem solution means.

Description

Improved chimney dust measuring device{.}

The present invention relates to a technique for measuring the concentration of dust contained in exhaust gas discharged from a chimney. More specifically, it relates to a technology that can improve the calibration method of the flue emission gas measurement device and easily align the optical axis during installation or maintenance work.

In the prior art prior to the present invention, a power supply unit and a CPU that emits a control signal according to a pre-installed program, a sensor unit that detects and measures pollutants discharged to the chimney, a drive motor that generates rotational force, and pollutants discharged from the chimney A driving unit having an air blower for suction, a heating line for maintaining the air blower and the CPU at room temperature, a lower pressure sensor for measuring a predetermined pressure, and a hype for measuring a pressure higher than the lower pressure sensor A body made of a leisure sensor, the switch unit connected to the air blower through a hose connector, and the power supply unit, CPU, sensor unit, driving unit, and a body functioning as a skeleton for receiving and fixing the switch unit, and installed outside the body, Disclosed is an apparatus including a filter box connected to the heating line through an air blower and filtering contaminants for which dust measurement has been completed.

In another prior art, a component and concentration measuring device of exhaust gas generates and irradiates infrared rays, a light source for irradiating infrared rays, a measurement cell for forming a traveling path of infrared rays, and a measurement cell for passing the exhaust gas in a direction perpendicular to the traveling direction of infrared rays, the first a photodetector comprising a first sensor for measuring a component and a second sensor for measuring a second component, and measuring an energy level of infrared rays passing through the exhaust gas using the first sensor and the second sensor; and Disclosed is a technology including a control unit for correcting the measured values of the first component and the second component measured by the first sensor using the measured values of the first component and the second component measured by the second sensor.

Registered Patent Publication No. 10-0776223 Registered Patent Publication No. 10-0910871

In the case of an existing dust meter, the luminous intensity of the light source may be changed by continuous measurement, and the dust attached to the front protection window that separates the chimney and the chimney dust meter of the present invention changes the measurement result using a reflective mirror. was correcting

However, this correction is whether the luminous intensity of the light source is changed. Since it is unknown whether the front protection window is dirty or not, there has been a problem of separately checking the replacement timing and defects of the light source.

In order to solve this problem, the present invention has attempted to solve this problem by further providing filters inside and outside the optical measurement unit based on the front hobo window.

In order to solve the above problems, the present invention provides the following problem solving means.

light source; and a half mirror through which light emitted from the light source passes; and

a reflector for reflecting the light in a 180 degree direction after the light passing through the half mirror passes through the optical axis inspection half mirror and passes through the chimney; and in an improved chimney dust measuring apparatus for measuring the amount of light in the transmitted light photodetector by rotating the light passing through the reflector by 90 degrees through the half mirror to measure the dust contained in the exhaust gas of the chimney,

It provides an improved chimney dust measuring device, characterized in that some of the light passing through the viewer half-mirror is rotated in 90 directions and sent to the viewer.

In addition, an optical axis inspection mirror is provided between the viewer and the viewer half-mirror, and an improved chimney dust measurement device is provided, characterized in that it further comprises an optical axis inspection sensor in the light reaching part of the optical axis inspection mirror.

In addition, it provides an improved chimney dust measuring device, characterized in that it further comprises an optical axis inspection sensor instead of the viewer.

In another configuration,

light source; and a half mirror through which light emitted from the light source passes; and

a reflector for the light passing through the half-mirror to pass through the rotating filter LINK2 and the rotating filter LINK1 sequentially, passing through the chimney, and then reflecting the light in a 180 degree direction; and the light passing through the reflector passes through the rotary filter LINK2 and the rotary filter LINK1 in reverse order, then rotates 90 degrees through the half mirror to measure the amount of light in the transmitted light photodetector to measure the dust contained in the exhaust gas of the chimney An improved chimney dust measuring device is provided.

In addition, at least one filter is provided in the rotary filter LINK1, and a mirror filter for correcting a light source is provided in the at least one filter.

In addition, the rotary filter LINK1 provides an improved chimney dust measuring device, characterized in that an empty filter, a mirror filter, a low light transmittance filter, a medium transmittance filter, and a high transmittance filter are provided.

In addition, the rotary filter LINK2 is provided with at least one filter, and the at least one filter provides an improved chimney dust measuring device, characterized in that it includes a blackbody filter that completely blocks light to measure a dark current.

In addition, the rotary filter LINK2 provides an improved chimney dust measuring device, characterized in that it includes a measuring filter, an empty filter, a mirror filter, and a blackbody filter.

The present invention has the effect of conveniently and efficiently calibrating the chimney dust measuring device and aligning the optical axis by the problem solving means as described above.

1 is a conceptual diagram of a conventional chimney dust measuring device;
2 is a conceptual diagram of adding a filter for calibration of the present invention;
3 is a conceptual diagram of the axis alignment means of the present invention;
4 is a filter used in the present invention;
5 is a calibration filter combination of the present invention;

When the effect of the present invention is described with reference to the drawings, it is as follows.

1 is a conceptual diagram of a conventional chimney dust measuring device. Looking at the optical path, light comes out from the light source 110 and goes straight through the half mirror 120 and is reflected by the reflector 130 , the direction of the light is changed 180 degrees, and again in the half mirror 120 counterclockwise 90 The direction is also changed to be incident on the transmitted light photodetectors PD1 and 140, and the intensity of light is measured.

Exhaust gas discharged from the chimney as light passes through the cross section of the chimney while it goes straight through the half mirror 120 and is reflected by the reflector 130 and the direction of the light is changed by 180 degrees and comes back to the half mirror 120 Measure the dust inside.

The measurement principle is to measure the total amount of dust discharged from the chimney by electrically measuring the difference in the amount of light before and after passing through the cross section of the chimney, and calculating that the reduced amount of light is due to dust.

1, the configuration of the zero compensation mirror 170 and the compensation reflection comparison mirror 150 can be seen. The optical measurement unit of the present invention of the front protection window 160 and the external environment are blocked. When the front protection window is contaminated with dust, it can be measured that there is a lot of dust during measurement. Although it is periodically cleaned to remove dust, it is calibrated at shorter intervals than that. This correction moves the zero point compensation mirror to the center of the optical axis formed between the light source and the reflector so that the light from the light source is incident into the chimney and is directly reflected from the zero point compensation mirror and measured without coming out through the reflector. will measure

Also, the path of the light generated from the light source passing through the half mirror and the reflector to the transmitted light photodetector may be changed due to various reasons. The optical axis can be checked through the compensation reflection comparison mirror.

However, the zero point can be measured and compensated for through the zero point compensation mirror, but it is not known whether the change in the amount of light is due to the contamination of the front protection window or the change in the light source. , the problem of the light source may not be known.

In addition, although the optical axis confirmation is essential for measurement accuracy, there is a disadvantage in that the operator has no choice but to manually check the optical axis with the naked eye.

The present invention aims to solve the above two problems. To this end, as shown in FIG. 2, a rotation filter link1 (190) and a rotation filter link2 (180) are further provided. The rotation filter LINK2 (180) is a further improvement of the existing zero point compensation mirror, and the rotation filter LINK1 (190) is further added to improve the performance of the present invention.

The configuration of the rotary filter LINK1 and the rotary filter LINK2 will be described using FIGS. 4 and 5 as follows. In Fig. 4, the rotation filter LINK1 is rotatably provided between the half mirror and the front protection window in the optical measurement chamber having the optical measurement unit therein. The rotary filter LINK1 includes M1, V1, F1, F2, and F3 filters, and the rotary filter LINK2 includes M2, V2, D1 and W1 filters. These filters are filters having the following functions, and the rotary filter LINK1 and the rotary filter LINK2 rotate with each other and perform a function by forming a specific combination.

M1: A mirror (mirror), which is a reflected signal and is used to correct the intensity of the light source.

M2: As a mirror (mirror), it is a reflected signal along with F1, F2, and F3.

- Conduct signal check (linearity test) of measuring instrument

V1: A passage for light to pass through an empty hole in the vacant

V2: A passage for light to pass through an empty hole in the vacant

F1: Filter for signal inspection of measuring instruments (high transmittance, more than 90%)

- It is a value with a low measurement concentration and is for equipment calibration.

F2: Filter for signal check of measuring instrument (medium transmittance, 70% or more) - Same function

F3 : Filter for signal check of measuring instrument (low transmittance, 50% or more) - same function

D1: dark, black body completely absorbs light

- Measure the dark current of the detector in the equipment with a signal with zero light

W1: window, a transparent window through which light always passes, and is a dust protection window attached to the optical system.

When used continuously, as the dust value increases due to dust on W1, the dust concentration caused by the dust on the window needs to be corrected. Measure the difference in influence and correct it by the concentration of dust attached to W1 to measure accurately.

Referring to Figure 5,

1) In general measurement, the rotary filter LINK1 uses the V1 filter and the rotary filter LINK2 places the W1 filter centered on the optical axis to measure the dust in the chimney.

2) In order to correct the light source, M1 of the rotary filter LINK1 is placed on the optical axis, the light is reflected from M1 and incident on the transmitted light photodetector, and the intensity of the light source is measured and the intensity of the light source is corrected.

3) Dark current compensation is to compensate for an electrically zero signal level by measuring the electrical signal measured by the transmitted light photodetector in a state where there is no light incident on the transmitted light photodetector by completely blocking the light. is V1 and the rotary filter LINK2 is D1, which is positioned on the optical axis to measure the signal of the transmitted light photodetector.

4) Pollution degree compensation is to compensate for the measurement error when contamination occurs in the measurement filter W1 including the front protection window. The contamination level is compensated by measuring the signal of the transmitted light photodetector.

The difference between the measurement result of the combination of V1 & V2 and the measurement result of V1 & W1 is calculated as the difference in the signal due to the dust polluted in W1, and this is compensated.

Another configuration of the present invention is the configuration of the optical axis inspection sensor. In the existing configuration, the optical axis was visually inspected through the viewer, but this is due to the visual inspection, which is problematic because it lacks objectivity and is performed irregularly when the chimney dust measurement is not well.

In order to solve the above problem, the present invention is equipped with an optical axis inspection mirror at the front end of the viewer and a CCD or PD (photo detector) having at least 2*2 pixels to monitor whether the optical axis is off-center. It provides a means for monitoring through a smart phone or the like remotely. On the other hand, it goes without saying that a CCD or a photo detector (PD) having at least 2*2 pixels can be provided at the position of the viewer.

In order to exhibit the above-mentioned effects, the following problem solving means are provided.

light source; and a half mirror through which light emitted from the light source passes; and

a reflector for reflecting the light in a 180 degree direction after the light passing through the half mirror passes through the optical axis inspection mirror and passes through the chimney; and in an improved chimney dust measuring apparatus for measuring the amount of light in the transmitted light photodetector by rotating the light passing through the reflector by 90 degrees through the half mirror to measure the dust contained in the exhaust gas of the chimney,

It provides an improved chimney dust measuring device, characterized in that some of the light passing through the viewer half-mirror is rotated in 90 directions and sent to the viewer.

In addition, an optical axis inspection mirror is provided between the viewer and the viewer half-mirror, and an improved chimney dust measurement device is provided, characterized in that it further comprises an optical axis inspection sensor in the light reaching part of the optical axis inspection mirror.

In addition, it provides an improved chimney dust measuring device, characterized in that it further comprises an optical axis inspection sensor instead of the viewer.

In another configuration,

light source; and a half mirror through which light emitted from the light source passes; and

a reflector for the light passing through the half-mirror to pass through the rotating filter LINK2 and the rotating filter LINK1 sequentially, passing through the chimney, and then reflecting the light in a 180 degree direction; and the light passing through the reflector passes through the rotary filter LINK2 and the rotary filter LINK1 in reverse order, then rotates 90 degrees through the half mirror to measure the amount of light in the transmitted light photodetector to measure the dust contained in the exhaust gas of the chimney An improved chimney dust measuring device is provided.

In addition, at least one filter is provided in the rotary filter LINK1, and a mirror filter for correcting a light source is provided in the at least one filter.

In addition, the rotary filter LINK1 provides an improved chimney dust measuring device, characterized in that an empty filter, a mirror filter, a low light transmittance filter, a medium transmittance filter, and a high transmittance filter are provided.

In addition, the rotary filter LINK2 is provided with at least one filter, and the at least one filter provides an improved chimney dust measuring device, characterized in that it includes a blackbody filter that completely blocks light to measure a dark current.

In addition, the rotary filter LINK2 provides an improved chimney dust measuring device, characterized in that it includes a measuring filter, an empty filter, a mirror filter, and a blackbody filter.

10: chimney
100: chimney dust meter
100' : Improved chimney dust meter
110: light source
120: half mirror
130: reflector
140: transmitted light photo detector PD1
150: Compensation reflection comparison mirror
160: front protection window
170: zero point compensation mirror
180: rotation filter LINK2
181 : D1
182 : V2
183 : W1
184 : M2
190: rotation filter LINK1
191: F1
192 : F2
193 : F3
194: V1
195: M1
200: half mirror for viewer
210: viewer
220: optical axis inspection mirror
230: optical axis inspection sensor 2*2

Claims (8)

light source; and
a half mirror through which light emitted from the light source passes; and
a reflector for reflecting the light in a 180 degree direction after the light passing through the half mirror passes through the optical axis inspection mirror and passes through the chimney; and
In an improved chimney dust measuring device, the light passing through the reflector rotates 90 degrees through the half mirror to measure the amount of light in the transmitted light photodetector to measure the dust contained in the exhaust gas of the chimney,
An improved chimney dust measuring device, characterized in that some of the light passing through the viewer half-mirror is rotated in 90 directions and sent to the viewer. According to claim 1,
An improved chimney dust measuring device comprising an optical axis inspection mirror between the viewer and the viewer half-mirror, and further comprising an optical axis inspection sensor at the light reaching part of the optical axis inspection mirror. According to claim 1,
Improved chimney dust measuring device, characterized in that it further comprises an optical axis inspection sensor instead of the viewer. light source; and
a half mirror through which light emitted from the light source passes; and
a reflector for the light passing through the half-mirror to pass through the rotating filter LINK2 and the rotating filter LINK1 sequentially, passing through the chimney, and then reflecting the light in a 180 degree direction; and
The light passing through the reflector passes through the rotary filter LINK2 and the rotary filter LINK1 in reverse order, then rotates 90 degrees through the half mirror to measure the amount of light in the transmitted light photodetector to measure the dust contained in the exhaust gas of the chimney Improved chimney dust measuring device. 5. The method of claim 4,
One or more filters are provided in the rotary filter LINK1, and a mirror filter for correcting a light source is provided in the one or more filters. 5. The method of claim 4,
The improved chimney dust measuring device, characterized in that the rotary filter LINK1 is provided with an empty filter, a mirror filter, a low light transmittance filter, a medium transmittance filter, and a high transmittance filter. 5. The method of claim 4,
The rotary filter LINK2 includes one or more filters, and the one or more filters include a blackbody filter that completely blocks light to measure dark current. 5. The method of claim 4,
The improved chimney dust measuring device, characterized in that the rotary filter LINK2 includes a measuring filter, an empty filter, a mirror filter, and a blackbody filter.

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