KR102408640B1 - Plastic gas cell for multi-gas leak alarm - Google Patents

Abstract

The invention of the present application makes an NDIR-type gas cell for gas measurement with plastic injection molding and makes it easy to fix the field mirror and the object mirror, and despite the distortion of the gas cell according to changes in the external environment, the field mirror and the object mirror An object of the present invention is to provide a plastic injection gas cell structure that minimizes changes in the relative position or distance of In order to achieve the above object of the present invention, a gas cell case for measuring plastic gas molded into an injection molding; and a screw hole for fixing the field mirror bracket formed at the bottom of the gas cell case. and a screw hole for fixing the object mirror bracket; and a field mirror fixing bracket coupled to the screw hole for fixing the field mirror. and an object mirror fixing bracket coupled to the screw hole for fixing the object mirror. and a field mirror fixed to the field mirror fixing bracket. and an object mirror fixed to the object mirror fixing bracket. and semicircular grooves are formed in the upper left and right sides of the field mirror so as not to block the light emitted from the light source and incident to the sensing unit, the light source is installed from the outside in the longitudinal direction of the gas cell case, and the sensing unit It provides a gas measuring cell, characterized in that.
According to the above configuration, the present invention does not change the position or deformation of the field mirror and the object mirror provided inside the plastic injection gas cell even when the external temperature changes,
There is also an effect of providing a gas cell having a simple structure by providing a structure for directly connecting the light source and the sensing unit to the gas cell.

Description

Plastic gas cell for multi-gas leak alarm{.}

The present invention is a technology related to a multi-gas leak alarm using a non-dispersive infrared gas meter. More specifically, it relates to improvements for mass production of gas cells, which are key components of non-dispersive infrared gas meters.

As a prior art prior to the filing of the present invention, a technology related to an optical composite gas measuring instrument and a measuring method is disclosed. This technology relates to an apparatus and method for measuring a complex gas using non-dispersive infrared rays. A light source generating light, a plurality of optical waveguides transmitting the light, a plurality of light detection sensors detecting the transmitted light, and the light source passing through any one of the plurality of optical waveguides, any one of the plurality of light detection sensors It is a technology including a driving unit for driving the light source to provide light as one.

As another prior art, a method that can measure the amount of CO2 generated or lost by plants during the process of culturing and storing plants in a confined space simply and precisely by using a non-dispersive infrared method is disclosed. have. A sample gas injection method was applied in using the non-dispersive infrared sensor, and the N 2 gas, which does not react to the sensor, is used as a carrier gas and a constant flow rate is controlled through a flow meter, the N 2 gas A step for allowing the sample gas to move to the sensor by installing a sample injection port in the movement path, a step for determining the flow rate of N 2 gas and an appropriate sample injection amount for each concentration range of the measurement gas, and a concentration calculation technique using a correction formula are disclosed.

As another prior art, there is disclosed a technique for setting a reference value of an optical gas meter and correcting the measured value. It is a technology that can change the gas measurement range of the gas meter linearly by making the standard gas cell of the calibration device of the optical gas meter continuously variable while maintaining the sealed state at the same pressure. In this technology, by varying the optical distance of the standard gas cell for measuring the gas concentration of the gas meter, it includes a variable standard gas cell that can set a plurality of gas concentration correction values. It relates to a technology that provides a correction function when calibrating with an optimal measuring instrument in the manufacturing process of setting the measuring range of a gas measuring instrument or changing the measuring range during measurement.

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Laid-Open Patent Publication No. 10-2017-0122873 Unexamined Patent Publication No. 2001-0090641 Registered Patent Publication No. 10-1879614

An object of the present application is to provide a means for mass production of a gas measurement cell that has been used for gas measurement in the ndir method. The conceptual diagram disclosed in FIG. 1 is a conceptual diagram of a basic NDIR (Non distributed Infra-Red Gas Detector). The non-dispersive infrared measurement method is not a method of measuring the absorbance using the spectralized light after spectroscopy, but irradiating the gas with light from a light source without spectroscopy and then filtering the light of a specific wavelength through optical filtering. It is a method of measuring the type and concentration of a gas by measuring the absorbance.

For this, a sufficient length of the optical path is required for the light from the light source to be absorbed by the gas. For this purpose, a gas cell as shown in FIG. 1 is used. A field mirror composed of one mirror is configured on one side, and an object mirror composed of two mirrors is configured on the other side. As a result, the entire optical path is lengthened, so that absorption of a specific wavelength by the gas inside the gas cell is sufficiently generated, so that the type and concentration of the gas can be measured by the sensing unit.

2 shows a method of conventionally processing a gas cell for measuring the gas. The inside is machined using an aluminum pipe or an aluminum rectangular block to complete the aluminum cell.

An incident mirror that reflects incident light at 90 degrees to the processed aluminum cell and sends it to an object mirror and an output mirror that reflects light at 90 degrees to a sensing unit for measurement are installed at a designed angle. Install the field mirror and object mirror in the following order.

The field mirror and the object mirror are fixed to the inside of the short side of the aluminum cell by using a screw from the outside of the aluminum cell in a three-point fixing method. Three screws are used for three-point fixing, and the installation angles of the field mirror and the object mirror are moved up, down, left and right by adjusting the length of the three screws.

Once the field mirror and the object mirror are temporarily fixed, a light source is installed, and light is incident from the outside. Angles of the one field mirror and the two object mirrors are adjusted so that the light incident from the light source reaches the sensing unit through the exit mirror.

Since the entire gas cell manufactured in this way is made of aluminum metal, a coil heater or a planar heating element is provided on the outside of the aluminum gas cell to heat the whole to always create constant measurement conditions, and the gas caused by changes in ambient temperature While there is an advantage that it can be adjusted so that there is no change in the length of the cell and the change of the mirror position, there has been a problem in that productivity is lowered because everything from processing to assembly has to be done manually. However, in the meantime, when a gas cell is made of plastic, fixing the field mirror and the object mirror due to deformation and distortion according to the surrounding environment of the gas cell has been a problem. In addition, in the case of a plastic injection molding, there is a problem in that a constant gas measurement environment cannot be created by heating as in an aluminum cell because heat conductivity is low due to having a heater outside. Due to this problem, the plastic injection gas cell could not be used in the field.

With the recent development of semiconductor technology, the price of parts for NDIR-type gas measurement devices, which could not be mass-produced in the past, has become cheaper. This is increasing.

However, in the case of the plastic injection gas measurement cell, the installation and adjustment of the mirror was not easy due to the deformation of the injection product due to the change in external temperature, so it could not be used.

According to the present invention, the gas cell is made of plastic injection molding and the mounting positions of the field mirror and the object mirror are easily installed, and the relative position or distance between the field mirror and the object mirror despite the cell twisting according to changes in the external environment. An object of the present invention is to provide a plastic injection gas cell structure that minimizes the change of

In addition, since the conventional gas cell has a flat mirror for incident light and output light, the size of the gas cell is increased and there are disadvantages of complexity. Another object of the present invention is to provide a gas cell for measuring gas in which a plane mirror for incident light and output light is removed.

The present invention provides a structure in which a gas cell for gas measurement, which was made of an existing aluminum block, as described above, using a plastic injection molding product can be made as follows.

Gas cell case for measuring plastic gas molded by injection molding; and

a screw hole for fixing the field mirror bracket formed at the bottom of the gas cell case; and

screw hole for fixing object mirror bracket; and

a field mirror fixing bracket coupled to the screw hole for fixing the field mirror; and

an object mirror fixing bracket coupled to the screw hole for fixing the object mirror; and

a field mirror fixed to the field mirror fixing bracket; and

an object mirror fixed to the object mirror fixing bracket; and

A semicircular groove is formed in the upper left and right sides of the field mirror so as not to block the light emitted from the light source and incident to the sensing unit, so that the light source is installed from the outside in the longitudinal direction of the gas cell case, and the sensing unit It provides a gas measuring cell characterized in that.

In addition, there is provided a gas measuring cell, characterized in that the groove formed on the side of the field mirror side of the gas cell case can be coupled to the light source and the sensing unit from the outside.

In addition, the field mirror is 10 degrees upward and 20 degrees downward with respect to the horizontal center of the sphere of a single radius; And it provides a gas measuring cell, characterized in that the mirror cut at an angle of 20 degrees to the left and right, respectively.

In addition, when the object mirror is viewed from the side in a state in which the center of a sphere having the same radius as the field mirror is moved to the side by 1/4 of the distance between the light source unit and the sensor unit, 20 degrees upward and 5 degrees downward; When viewed from above, the right side of the object mirror is 20 degrees to the right, and the left side of the object mirror is 20 degrees to the left.

In addition, the field mirror and the object mirror are installed to face each other so that the left and right centers coincide when viewed from above, and the center of the axis of the light source and the center of the sensing unit are on a horizontal line passing through the center of the field mirror when viewed from the side. The center of the object mirror is positioned as high as 1/12 of the radius than the center of the field mirror, and the distance between the horizontal center is the field mirror and the object mirror while the light of the light source is incident and reflected between the field mirror and the object mirror. It provides a gas measurement cell, characterized in that the horizontal distance between the center of the field mirror and the center of the object mirror is the radius of the sphere (R) ± 1/12 R so as not to deviate from the size of.

In addition, the field mirror provides a gas measurement cell, characterized in that the coupling portion is formed with a total of three field mirror brackets, one at the center of the top and one on the left and right with respect to the center of the bottom.

In addition, the object mirror provides a gas measurement cell, characterized in that the coupling portion is formed with all four object mirror brackets, one each symmetrically from the upper center and one each on the left and right symmetrically with respect to the lower center.

In addition, the field mirror bracket and the object mirror bracket are coupled only to the gas cell case and the lower part, and the side, rear and upper surfaces are spaced apart from the gas cell case and coupled to the gas cell case in which the plastic is injected due to a change in external temperature. There is provided a gas measuring cell, characterized in that it is configured to minimize the effect of the deformation on the field mirror bracket and the object mirror bracket.

In addition, the gas cell case may further include an outer case to protect the gas cell case and to be attached to the device, wherein the outer case and the gas cell case are on one side of the gas cell case in the overall longitudinal direction. It provides a gas measurement cell, characterized in that by fixing the three-point coupling and fixing biased toward the possible end, the deformation by the outer case whose length is changed according to the external temperature is fixed to minimize the influence on the gas cell case.

The present invention provides an effect of providing a plastic injection gas cell that is not affected by external temperature change because distortion of the field mirror and object mirror provided inside the plastic injection gas cell does not occur even when the external temperature changes due to the configuration as described above. there is

In addition, by providing a structure for directly connecting the light source and the sensing unit to the gas cell, there is an effect of providing a gas cell having a simple structure.

1 is an NDIR gas measurement cell structure using a conventional method;
2 is a gas cell manufacturing method used for gas measurement in the conventional NDIR method.
3 is a gas cell mirror calibration method of an aluminum gas cell of the conventional NDIR method.
Figure 4 is the structure of the plastic injection gas cell of the present invention
Figure 5 shows the mounting position of the plastic injection gas cell of the field mirror bracket and the object mirror bracket of the present invention
6 is a view of fixing the field mirror bracket to the field mirror of the present invention
7 is a view of fixing the object mirror bracket to the object mirror of the present invention
Figure 8 is a shape plan view of the object mirror of the present invention
9 is a side view and a light path (red color) of the field mirror and the object mirror of the present application
10 is a plan view of an optical path of the present invention;
11 is a side cross-sectional view in which the field and object mirror brackets of the present invention are actually fixed;
12 is a side cross-sectional view of a plastic injection gas cell fixed to the outer case of the present invention;

The operation and effect of the present invention will be described using the drawings as follows.

1 shows the structure of an NDIR gas measurement cell using a conventional method. In general, a gas cell is made of a metal material. It is common to use the inside of an aluminum block that is easy to process. It is constructed by cutting out the inside of the rectangular block, making an inlet and an outlet through which gas can flow, and installing a field mirror and an object mirror. In FIG. 1, an incident mirror and an exit mirror are further provided for the incident and emission of light.

FIG. 2 shows a method of manufacturing a gas cell used for gas measurement in the conventional NDIR method. Cut the inside of the aluminum block (A) to make a gas cell. Install the incident mirror (light source mirror) and the exit mirror (measuring mirror) at the designed angle (B) Install the field mirror and object mirror in the gas cell (C, D) Install a light source or laser outside to change the optical path After making it possible to check, adjust the field mirror and object mirror to adjust the optical path.

3 shows a gas cell mirror calibration method of an aluminum gas cell of the conventional NDIR method. The field mirror and the object mirror use three screws from the outside of the gas cell to adjust the positions and vertical and horizontal angles of the respective mirrors. By adjusting the angle in this way, the incident light source accurately reaches the sensing unit provided at the exit.

Figure 4 shows the structure of the plastic injection gas cell of the present invention. It can be seen that a protrusion is formed vertically on the outside of the plastic injection gas cell to prevent deformation due to heat and temperature as much as possible, and a cross-shaped protrusion is provided on the inner bottom of the screw joint to increase the bonding strength and to prevent deformation according to temperature. designed to be minimized.

Nevertheless, since there may be deformation of the plastic injection gas cell, the field mirror bracket and the object mirror bracket are coupled to the bottom of the plastic injection gas cell at two places, and in order not to be affected by external deformation, the other part is the plastic It is provided to be spaced apart from the wall of the injection gas cell. Figure 5 shows the mounting position of the plastic injection gas cell of the field mirror bracket and the object mirror bracket of the present invention.

6 and 7 show views in which the field mirror bracket and the object mirror bracket are respectively fixed to the field mirror and the object mirror of the present application.

In order to prevent deformation of the field mirror and the object mirror, each mirror is not directly coupled to the plastic injection gas cell, but only two points are coupled and fixed to the vertical wall surface of each bracket coupled to the lower portion. By fixing in this way, it is a feature of the present invention that the respective mirrors are not deformed despite the deformation of the plastic injection gas cell.

The shape of the field mirror is 10 degrees upward and 20 degrees downward with respect to the horizontal center of the sphere of a single radius; and a spherical surface cut at an angle of 20 degrees from side to side, respectively, is used as the surface of the mirror. Here, semicircular grooves were formed on the left and right side optical paths of the field mirror so as not to block the light from the light source and the light incident on the sensing unit through the gas cell.

In addition, the shape of the object mirror is 20 degrees upward and 5 degrees downward when viewed from the side, with the center of a sphere having the same radius as the field mirror moved laterally by 1/4 of the distance between the light source unit and the sensing unit. When viewed from above, the spherical surface cut into an area of 20 degrees to the right on the right side of the object mirror and 20 degrees to the left on the left side of the object mirror was constituted as the surface of the mirror.

8 is a top view of the shape of the object mirror according to the present application. A spherical surface formed by separating two identical spheres by 1/12 of the radius R of the sphere is used as the surface of the mirror.

The length of 1/12 R is equal to the distance the light travels from the light incident part to the light output part by reflection once on the optical path in FIG. 10 .

9 shows a side view and an optical path (red color) of the field mirror and the object mirror according to the present invention. The light incident part and the light output part of the field mirror are directed toward the object mirror while forming a horizontal line, and the parallel light reaching the object mirror arrives at the field mirror again at a constant angle and returns to the object mirror at the same reflection angle, and the parallel light again It repeats the optical path back to the field mirror in the form of

10 is a plan view of the optical path of the present application, and it can be seen that the incident light source moves from the light source to the sensing unit while repeatedly returning and going between the object mirror and the field mirror.

The moving distance is 1/12 R of the radius of the sphere, and this length is equal to the distance between the centers of two spheres spaced apart from the object mirror as described above.

11 is a side cross-sectional view showing the field and object mirror brackets of the present invention are actually fixed, and the field and object mirror brackets of the invention of the present application are only coupled to the plastic injection gas cell and the lower part, and the remaining parts are separated.

12 is a side cross-sectional view in which the plastic injection gas cell is fixed to the outer case of the present invention. In order to prevent deformation of the plastic injection gas cell by the outer case when an outer case is required, the plastic injection gas is coupled only on one side in the longitudinal direction and the other side is supported in spite of the deformation in the longitudinal direction of the outer case. It was configured to minimize the deformation of the cell.

The configuration of the invention showing the above-described effects of the present invention is as follows.

Gas cell case for measuring plastic gas molded by injection molding; and

a screw hole for fixing the field mirror bracket formed at the bottom of the gas cell case; and

screw hole for fixing object mirror bracket; and

a field mirror fixing bracket coupled to the screw hole for fixing the field mirror; and

an object mirror fixing bracket coupled to the screw hole for fixing the object mirror; and

a field mirror fixed to the field mirror fixing bracket; and

an object mirror fixed to the object mirror fixing bracket; and

A semicircular groove is formed in the upper left and right sides of the field mirror so as not to block the light emitted from the light source and incident to the sensing unit, so that the light source is installed from the outside in the longitudinal direction of the gas cell case, and the sensing unit It provides a gas measuring cell characterized in that.

In addition, there is provided a gas measuring cell, characterized in that the groove formed on the side of the field mirror side of the gas cell case can be coupled to the light source and the sensing unit from the outside.

In addition, the field mirror is 10 degrees upward and 20 degrees downward with respect to the horizontal center of the sphere of a single radius; And it provides a gas measuring cell, characterized in that the mirror cut at an angle of 20 degrees to the left and right, respectively.

In addition, when the object mirror is viewed from the side in a state in which the center of a sphere having the same radius as the field mirror is moved to the side by 1/4 of the distance between the light source unit and the sensor unit, 20 degrees upward and 5 degrees downward; When viewed from above, the right side of the object mirror is 20 degrees to the right, and the left side of the object mirror is 20 degrees to the left.

In addition, the field mirror and the object mirror are installed to face each other so that the left and right centers coincide when viewed from above, and the center of the axis of the light source and the center of the sensing unit are on a horizontal line passing through the center of the field mirror when viewed from the side. The center of the object mirror is positioned as high as 1/12 of the radius than the center of the field mirror, and the distance between the horizontal center is the field mirror and the object mirror while the light of the light source is incident and reflected between the field mirror and the object mirror. It provides a gas measurement cell, characterized in that the horizontal distance between the center of the field mirror and the center of the object mirror is the radius of the sphere (R) ± 1/12 R so as not to deviate from the size of.

In addition, the field mirror provides a gas measurement cell, characterized in that the coupling portion is formed with a total of three field mirror brackets, one at the center of the top and one on the left and right with respect to the center of the bottom.

In addition, the object mirror provides a gas measurement cell, characterized in that the coupling portion is formed with all four object mirror brackets, one each symmetrically from the upper center and one each on the left and right symmetrically with respect to the lower center.

In addition, the field mirror bracket and the object mirror bracket are coupled only to the gas cell case and the lower part, and the side, rear and upper surfaces are spaced apart from the gas cell case and coupled to the gas cell case in which the plastic is injected due to a change in external temperature. There is provided a gas measuring cell, characterized in that it is configured to minimize the effect of the deformation on the field mirror bracket and the object mirror bracket.

In addition, the gas cell case may further include an outer case to protect the gas cell case and to be attached to the device, wherein the outer case and the gas cell case are on one side of the gas cell case in the overall longitudinal direction. It provides a gas measurement cell, characterized in that by fixing the three-point coupling and fixing biased toward the possible end, the deformation by the outer case whose length is changed according to the external temperature is fixed to minimize the influence on the gas cell case.

100: plastic injection gas cell
110: lower gas cell case
115: gas cell case lid
120: light source fixing part
130: sensing unit fixed part
140: field mirror bracket fixing part
150: object mirror bracket fixing part
160: lower gas cell case leg
170: bracket and gas cell case space
180: gas cell fixing screw
200: field mirror
210: field mirror lower fixing part
220: field mirror upper fixing part
230: field mirror light source part groove
240: field mirror sensing unit groove
250: field mirror bracket
260: field mirror bracket fixing groove
270: field mirror bracket fixing claw
300: object mirror
310: object mirror lower fixing groove
320: object mirror upper fixing groove
350: object mirror bracket
360: object mirror bracket fixing groove
400: outer case

Claims (9)

Gas cell case for measuring plastic gas molded by injection molding; and
a screw hole for fixing the field mirror bracket formed at the bottom of the gas cell case; and
screw hole for fixing object mirror bracket; and
a field mirror fixing bracket coupled to the screw hole for fixing the field mirror; and
an object mirror fixing bracket coupled to the screw hole for fixing the object mirror; and
a field mirror fixed to the field mirror fixing bracket; and
an object mirror fixed to the object mirror fixing bracket; and
A semicircle-shaped groove is formed in the upper left and right sides of the field mirror so as not to block the light emitted from the light source and incident to the sensing unit, the light source is installed from the outside in the longitudinal direction of the gas cell case, and the sensing unit is installed,
A groove in which the light source and the sensing unit can be coupled from the outside is formed on the short side of the field mirror side of the gas cell case,
The field mirror is 10 degrees upward and 20 degrees downward with respect to the horizontal center of the sphere of a single radius; and a mirror cut at an angle of 20 degrees to the left and right, respectively,
When the object mirror is viewed from the side in a state in which the center of a sphere having the same radius as the field mirror is moved laterally by 1/4 of the distance between the light source and the sensing unit, the object mirror is viewed from the top by 20 degrees upward, 5 degrees downward, and viewed from above. When the right side of the object mirror is 20 degrees to the right, the left side of the object mirror is a mirror cut into an area of 20 degrees to the left,
The field mirror and the object mirror are respectively opposite to each other and installed so that the left and right centers coincide when viewed from above, and the center of the axis of the light source and the center of the sensing unit are provided on a horizontal line passing through the center of the field mirror when viewed from the side, The center of the object mirror is located higher than the center of the field mirror by 1/12 of the radius, and the distance between the horizontal center is the size of the field mirror and the object mirror while the light from the light source is incident and reflected between the field mirror and the object mirror The horizontal distance between the center of the field mirror and the center of the object mirror is the radius (R) of the sphere ± 1/12 R,
The field mirror has a coupling portion with three field mirror brackets, one at the center of the upper end and one on the left and right with respect to the center of the lower end,
The object mirror is formed with a coupling portion with a total of four object mirror brackets, one each symmetrically from the upper center and one each on the left and right symmetrically with respect to the lower center,
The field mirror bracket and the object mirror bracket are only coupled to the gas cell case and the lower part, and the side, rear and upper surfaces are spaced apart from the gas cell case and coupled to the deformation of the plastic-injected gas cell case due to changes in external temperature. It is configured so that the effect of the effect on the field mirror bracket and the object mirror bracket is minimized,
The gas cell case may further include an outer case to protect the gas cell case and to be attached to and installed on the device, wherein the outer case and the gas cell case are at one end possible in the entire longitudinal direction of the gas cell case. A plastic gas cell for a multi-gas leak alarm, characterized in that it is fixed to minimize the influence of the gas cell case by deformation by the outer case whose length is changed according to the external temperature by fixing the three-point coupling biased to the outer temperature. delete delete delete delete delete delete delete delete

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