KR101879614B1 - Device for setting reference and calibrating measurement of the optical type gas analyzer - Google Patents

Abstract

The present invention provides a device for setting a reference and calibrating a measurement of an optical type gas analyzer, whereby pressure of a standard gas cell in the device is continuously variable while being held at the same value so as to allow a measurement range of the gas analyzer to be linearly changed. To this end, the device includes a variable standard gas cell for measuring a concentration of gas in the gas analyzer, wherein an optical distance of the standard gas cell is varied so that a plurality of calibrated values can be set for gas concentration, thereby providing an optimally calibrated gas analyzer during the manufacturing process in which a measurement range of the gas analyzer is set, or providing an efficient calibrating function in the event of varying the measurement range even during measurement.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical gas meter,

The present invention relates to a reference value setting apparatus and an apparatus for correcting a measured value of an optical gas meter, and more particularly, to a gas meter By setting the measurement range of the gas measuring instrument by changing the range linearly, it is possible to calibrate with the optimum measuring instrument in the manufacturing process or to set the reference value of the optical gas measuring instrument which can provide an efficient correction function when the measuring range is to be changed during measurement And a measurement value correcting device.

Fig. 1 is a diagram illustrating the basic structure of a general gas measuring instrument. The basic structure of a gas measuring instrument is shown in Fig. 1. The basic structure of the gas measuring instrument includes a light source 1, an optical filter 2, an inlet 3a and an outlet 3b, A sample cell 3, a standard gas cell 4, and a photodetector 5, and a basic principle thereof is a Beer Lambert's law law defined by Equation (1) below.

Where I is the initial light of the light source, alpha is the extinction coefficient of the gas molecule, L is the distance of the light source passage, i.e., the length of the gas cell, and c is the concentration of the gas.

In other words, the concentration (c) of the desired gas is obtained through the relationship between I and Io.

At this time, the optical filter 2 is a filter used for selecting light that causes a particularly absorbing reaction to a specific gas (for example, CO, CO ₂ , SO _{2 and the} like) But may be located between the sample cell 3 and the gas sample cell 3 and the photodetector 5.

1, an optical lens and a mirror for efficiently passing the light path and light between the light source 1 and the photodetector 5 can be added for each device.

Meanwhile, the standard gas cell 4 may be omitted in a part of its structure, but its role plays a complementary function such as concentration correction of a gas measuring instrument, setting of a reference value, etc., and a plurality of gas cells may be used depending on the type of gas to be measured , It is a main function to set the reference value when calibrating the initial gas meter by sealing the gas.

When a plurality of standard gas cells are held, the correction value optical filter may also be used as a multimeter at the same time.

A plurality of standard gas cells are also used in some cases as a term of a gas filter correlation.

The characteristics of the standard gas cell are fixed with the standard gas sealed. In a plurality of cases, as described in Korean Patent No. 10-1014245 (refer to reference numeral 11 in FIG. 1), a plurality of And is used as a correction value when converting the concentration of a specific gas. That is, a plurality of cells can be used for analogy of measurements through rotation.

However, since the standard gas cell of the correction device in the optical gas meter can not be continuously changed, it is impossible to set a plurality of standard gas measurement values of the gas meter, so that the standard gas cell must be changed whenever necessary, Since the internal pressure needs to be adjusted again each time the gas cell is changed, the linearity deteriorates. Therefore, there are many methods of changing the standard gas concentration of the standard gas cell or securing the linearity of the section by multipoints by constructing a plurality of standard gases There was a drawback that it took time.

KR 10-1014245 B1 Registered on 2011.02.07

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a gas gauge for a gas gauge for an optical gas meter, The gas measuring range of the gas measuring instrument can be changed linearly so that the measuring range of the gas measuring instrument can be set. In the manufacturing process, it is possible to calibrate with an optimum measuring instrument or to provide an efficient correction function And to provide a reference value setting and an apparatus for correcting a measured value of an optical gas measuring instrument.

In order to achieve the above object, an embodiment of the present invention includes a variable standard gas cell in which an optical distance of a standard gas cell for measurement of gas concentration of an optical gas meter is varied to set a plurality of gas concentration correction values A reference value setting and a measurement value correcting device for an optical gas measuring instrument.

According to the present invention, the standard gas cell of the correction device in the optical gas measuring device can be continuously varied while maintaining the state of being sealed at the same pressure, and by specifying a plurality of standard gas concentration measurement values of the gas measuring device, It is possible to secure a higher level in the fixed standard gas cell and to change the measurement range of the gas measuring device which can be set in the initial manufacturing process in the operating condition of the measuring device, The gas measuring instrument of the present invention provides an advantage of providing an efficient correction function when it is desired to calibrate with the gas measuring instrument of the present invention or to change the measurement range during measurement.

1 is a schematic view illustrating the basic structure of a general optical gas measuring instrument.
2 is a schematic view illustrating the structure of a reference value setting and measurement value correcting device of an optical gas measuring instrument according to an embodiment of the present invention.
FIG. 3 is a schematic view illustrating an installation state of a variable-type standard gas cell applied to an in-situ type, as a structure of a reference value setting and measurement value correcting device of an optical gas meter according to another embodiment of the present invention.
4 (a) to 4 (d) are reference views showing examples in which reference value setting and measurement value correcting apparatuses of the optical gas measuring instrument according to the present invention are applied to different kinds of gas measuring instruments.
5 is a detailed view exemplifying an example in which the reference value setting and measurement value correcting device of the optical gas measuring instrument according to each embodiment of the present invention is configured to manually adjust the length of the variable standard gas cell.
6 is a schematic diagram illustrating a method of automatically setting the reference value of the optical gas measuring instrument according to each embodiment of the present invention and the length of the variable standard gas cell in the measurement value correcting apparatus.
7 (a) and 7 (b) are graphs showing the relationship between the reference value of the optical gas measuring instrument according to the present invention and the state in which the gas concentration correction value is set to the minimum (L ") by adjusting the length of the variable standard gas cell in the measurement value correcting device (a) and a state (b) in which the maximum value (L ') is set.
8 (a) and 8 (b) are enlarged cross-sectional views of portions A and B of Figs. 7 (a) and 7 (b)

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, reference value setting and measurement value correcting device of the optical gas measuring instrument according to the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that the words or words used in the present specification and claims are not to be construed in a conventional or dictionary sense and that the inventor can properly define the concept of a term in order to describe its invention in the best possible way And should be construed in light of the meanings and concepts consistent with the technical idea of the present invention. Therefore, it should be understood that the embodiments described herein and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and that various equivalents and modifications may be substituted for them at the time of the present application shall.

FIG. 2 is a schematic diagram illustrating the structure of a reference value setting and measurement value correcting apparatus of an optical gas measuring instrument according to an embodiment of the present invention, and FIG. 3 is a diagram showing a reference value setting and measurement of an optical gas measuring instrument according to another embodiment of the present invention 2 and 3, the reference value setting and measurement value correcting device of the optical gas measuring instrument according to the present invention, as shown in FIGS. 2 and 3, is a schematic view illustrating an installation state of a variable standard gas cell applied to an in- And a variable standard gas cell 100 capable of varying the optical distance of the standard gas cell 110 for measuring the gas concentration of the optical gas meter and setting a plurality of the gas concentration correction values.

In particular, in the case of a variable standard gas cell applied to an in-situ type gas meter, this variable standard gas cell 110 is reflected by the mirrors 6, 7 and then placed on the front of the optical detector 5 of the meter body, When a plurality of gas measurements are required, two or more of them may be positioned on a disk-shaped rotating plate so that a plurality of gases can be measured by rotation.

4 (a) to 4 (d) are reference views showing an example in which the reference value setting and measurement value correcting device of the optical gas measuring instrument according to the present invention is applied to different kinds of gas measuring instruments, 100 is a reflection type gas measuring device in which a light source and a detector are located on the same side and a light reflector is used as illustrated in FIG. 4 (a), or a reflective gas measuring device using a light source, a gas cell, A gas measuring instrument of the type in which the light emitted from the light source is separated into two or more by using a beam splitter and the two detectors are arranged at the end, as shown in FIG. 4 (c) As shown in FIG. 4 (d), it can be implemented by applying to a gas measuring instrument in which light emitted from a light source is separated into two or more beams by using a beam splitter and one detector is arranged at the end, have. Hereinafter, a description will be made of a representative example of a state in which the variable gas cell of the present invention is applied to a reflection type gas measuring instrument in which a light source and a detector are located on the same side. In a case where the present invention is applied to other types of gas measuring instruments A detailed description thereof will be omitted.

5 is a detailed view exemplifying an example of manually adjusting the length of the variable standard gas cell in the reference value setting and measurement value correcting device of the optical gas measuring instrument according to each embodiment of the present invention, A reference value setting method of an optical gas measuring instrument according to each embodiment of the present invention and a method of automatically varying the length of a variable standard gas cell in a measured value correction apparatus, The auxiliary cell 130 having the same structure as that of the standard gas cell 110 is connected to the connection pipe 120 so that the extra standard gas can be transferred to keep the internal pressure constant when the length of the standard gas cell 110 is changed, As shown in FIG.

The standard gas cell 110 is composed of a hollow first hollow tube 111 (for example, a bellows or the like) which can freely adjust the length thereof and has no obstacle therein, so that a light path of the light emitted from the light source 1 Both ends of the first corrugated tube 111 are sealed and supported by the left support table 113a and the right support table 113b in which the gas inlet 112a and the gas outlet 112b are formed, do. The standard gas cell 110 may be configured to be manually or automatically adjustable in length.

In the case where the standard gas cell 110 is configured to be manually adjustable, as shown in FIG. 5, the standard gas cell 110 is configured such that any one of the left and right supports 113a, And the other one of the left and right support rods 113a and 113b is movably supported to the left and right along the guide 114 so that the length of the first corrugated pipe 111 can be varied. At this time, the guide 114 displays a scale for use in adjusting the gas concentration correction value of the standard gas cell 110, and this scale is used when the length L of the first bell pipe 111 is extended to the maximum, The gas concentration correction value of the standard gas cell 110 when the gas concentration correction value of the cell 110 indicates the maximum value (L = L ') and the length L of the first bell pipe 111 is minimized It is preferable to set to display the minimum value (L = L "= 0).

When the standard gas cell 110 is configured to be automatically adjustable, as shown in FIG. 6, one of the left and right support rods 113a and 113b is connected to one side of the linear motor 116 And the other one of the left and right support rods 113a and 113b is movably supported to the left and right along the linear motor 116 so that the length of the first corrugated tube 111 can be varied . The linear motor 116 is a small-sized linear motor that is precisely controllable and is controllably connected to the linear motor driving unit 117 and the control unit 118 so that the linear motor 116 is controlled by the control unit 118 and the linear motor driving unit 117, The length of the first corrugated tube 111 of the standard gas cell 110 becomes automatically adjustable as the support shaft 116 is automatically driven and the support member, which is fixedly supported and supported on the support shaft, is moved along the linear motor 116.

7 (a) and 7 (b) are graphs showing the relation between the reference value of the optical gas measuring instrument according to the present invention and the measured value correcting device by adjusting the length L of the variable standard gas cell, (A) and (b) of FIG. 7 (a) and FIG. 7 (b), respectively. As shown in FIG. 7A, the variable standard gas cell 100 has a maximum length L of the first corrugated pipe 111 of the standard gas cell 110, The gas concentration correction value of the standard gas 110 is set to a maximum value (L = L ') or the body length L of the first bell pipe 111 is compressed to a minimum as shown in FIG. 7 (b) The gas concentration correction value of the cell 110 can be set to the minimum value (L = L "= 0).

In order to set the gas concentration correction value by the cell to the zero state in a state where the length of the standard gas cell 110 is minimized, the standard gas cell 110 is irradiated with infrared rays (IR) or ultraviolet rays Glass windows 115a and 115b through which the ultraviolet (UV) light can pass can be formed as shown in FIG. 8 (a). Also, in order to prevent the case where the gas measurement section of the gas measuring instrument can not be used due to the space occupied by the left and right support rods 113a and 113b, the standard gas cell 110 has a measurement range of 5% As shown in FIG.

However, since the optical distance Lc of the gas sample cell 3 of the gas measuring instrument and the maximum distance L 'of the standard gas cell 110 are not equal to each other, the measurement range of the gas measuring instrument is set to (Lc / L') * 1.05 times It can be said that the standard gas of the corresponding concentration is injected into the standard gas cell 110. In addition, in order to change the measuring range of the measuring device, it is possible to add the measuring range by considering the variable range. For example, if you extend the measurement range by 20%, a standard gas cell with standard gas calculated at 1.25 instead of 1.05 is used. It should be noted here that Lc, L ', etc. are pure optical paths that go into the gas cell.

The connection pipe 120 is connected to one of the gas inlet 112a and the gas outlet 112b of the standard gas cell 110 and connected to the gas inlet 132a and the gas outlet 132b of the auxiliary cell 130, 132b of the standard gas cell 110 and the auxiliary cell 130. The connection pipe 120 is connected to one of the standard gas cell 110 and the auxiliary cell 130, 130 remain the same.

The auxiliary cell 130 is provided at a position other than the optical path, which is constituted by a hollow second bell pipe 131 (for example, a bellows or the like) which can freely adjust the length and has no obstacle therein, Both ends of the second bell pipe 131 are sealed by the left and right support rods 133a and 133b formed with the gas inlet 132a and the gas outlet 132b so as to be able to perform the internal pressure and temperature measurement, 134 and a temperature sensor 135. One of the gas inlet 132a and the gas outlet 132b is connected to the other side of the connection pipe 120 and connected to the standard gas cell 110 ). ≪ / RTI > Here, the pressure sensor 134 is installed in the cell to measure the internal pressure of the auxiliary cell 130, and the indicator is installed to expose the upper part of the cell cover. The temperature sensor 135 is disposed inside the auxiliary cell 130 A sensing unit is installed inside the cell to measure the temperature, and the indicator is installed to expose the upper part of the cell cover. This enables the temperature sensor 135 and the pressure sensor 134 to display the standard gas state in the variable standard gas cell 100 and can be utilized as input data when checking the gas meter. It is desirable to treat these gases in the laboratory so that they are normally used at 1 atmospheric pressure 25 ° C.

On the other hand, in the auxiliary cell 130, a convex dummy block 136 which can favorably control the amount of the internal gas to the inside of one of the left and right support rods 133a, And can be illustrated as illustrated.

In this configuration, the standard gas cell 110 maintains a state in which the body length is maximally extended when the initial standard gas is injected, and the auxiliary cell 130 is initialized such that the gas injection is performed in a state where the body length is minimized. .

The reference value setting and the operation and operation of the measurement value correcting device of the optical gas measuring instrument according to the present invention constructed as above will be described as follows.

First, the reference value setting of the optical gas measuring instrument according to the present invention and the measurement principle of the measurement value correcting device are such that when the incident light has the same cross section, the change of the length L of the optical cell (optical path) is proportional to the gas concentration c The change of the light absorption is based on Beer Lambert's law as defined by Equation 1 defining a relationship in which the light path L is in inverse proportion to the light path L. The light path L ) Can be extended or reduced to adjust the overall concentration.

That is, in the gas measurement period located on the optical path of the light emitted from the light source 1 of the optical gas measuring instrument as illustrated in FIGS. 2 and 3, the standard gas cell 110 of the variable standard gas cell 100 And the auxiliary cell 130 is connected to one side of the standard gas cell 110 through the connection pipe 120 so as to communicate with the standard gas cell 110 in one space.

At this time, the standard gas cell 110 and the auxiliary cell 130 are constituted by the first and second bellows pipes 111 and 131 except for the left and right support rods 113a, 113b, 133a and 133b, respectively, And the auxiliary cell 130 is connected to the standard gas cell 110 through the connection pipe 120 to allow the standard gas cell 110 to pass through the standard gas cell 110, Even if a change occurs in the body length of the body 110,

Next, the first standard gas is injected using the gas inlet / outlet ports 112a, 112b, 132a, and 132b of the standard gas cell 110 and the auxiliary cell 130. At this time, The remainder is used as an outlet, and the injection of the initial standard gas injects the gas in a state that the standard gas cell 110 has the maximum extended length and the auxiliary cell 130 has the minimum reduced length.

By changing the length of the standard gas cell 110 in the direction of the arrow in FIG. 5 in the state where the standard gas is injected as described above, the gas concentration correction value of the optical gas measuring instrument can be linearly changed. In this case, the empty space of the gas measuring section where the standard gas cell 110 is not present assumes that the concentration of the noxious gas is zero. This is because the gas concentration measuring range of the gas measuring instrument is several thousand times as large as the atmospheric concentration, .

Meanwhile, a change in the length of the standard gas cell 110 of the variable standard gas cell 100 installed on the optical path can be adjusted manually or automatically. When the length of the standard gas cell 110 is manually adjusted, The upper end portions of the left and right support rods 113a and 113b of the standard gas cell 110 are fixed and supported by the guide 114 so as to vary the length of the first corrugated pipe 111 . At this time, any one of the left and right support rods 113a and 113b (corresponding to the left support rope in the drawing, for example) is fixed so as not to move by the guide 114 and the other (e.g., To the left and right along the guide 114. The guide 114, The length of the first corrugated tube 111 can be varied so that the length of the standard gas cell 110 can be varied so that the length of the standard gas cell 110 can be varied. It is possible to adjust the gas concentration correction value. Since the scale 114 is displayed on the guide 114, the right support 113b reads the scale at the corresponding position, so that the gas concentration correction value to be checked by the gas meter can be adjusted.

On the other hand, when the length of the standard gas cell 110 is automatically controlled, the upper ends of the left and right support rods 113a and 113b of the standard gas cell 110 are linearly driven by the linear motor 116 So that the length of the first bellows pipe 111 can be varied. At this time, any one of the left and right support rods 113a and 113b (for example, the left support rope in the drawing) is fixed by one side of the linear motor 116 so as not to move, To the left and right along the linear motor 116 so as to be able to flow. The linear motor 116 is controllably connected to the linear motor driving unit 117 and the control unit 118 so that the linear motor 116 is automatically driven by the control unit 118 and the linear motor driving unit 117 The length of the first corrugated pipe 111 can be changed by moving the right support 113b along the linear motor 116 in the direction of the arrow (left and right) Can be varied to automatically adjust the gas concentration correction value.

At this time, when the standard gas cell 110 is fully compressed as illustrated in FIG. 7 (a) and the gas of the optical gas meter is in the zero state, the standard gas cell 110, as illustrated in FIG. 8 (a) The windows 115a and 115b passing through the optical path are embedded in the left and right support rods 113a and 113b of the body so that the windows 115a and 115b of the left and right support rods 113a and 113b And 115b are brought into contact with each other to form a zero state. Conversely, when the standard gas cell 110 is maximally extended to maximize the gas of the optical gas meter as illustrated in FIG. 7 (b), the right support 113b, The scale of the guide 114 or the linear motor 116 instructed by the controller 114 indicates the maximum gas concentration correction value.

In addition, since the space occupied by the left and right support rods 113a and 113b of the standard gas cell 110 can not be used in all of the gas measuring ranges of the gas measuring instrument, By using more than% standard gas, it is possible to make continuous change from zero to measurement range without utilizing all the measurement period.

Since the actual standard gas cell 110 may be much smaller than the optical distance Lc of the gas sample cell 3 of the gas meter, the concentration of the standard gas injected into the standard gas cell 110 may be estimated Measuring instrument concentration range) * (Lc / L ') * 1.05 standard gas is set.

8B is an enlarged view of the left and right support rods 133a and 133b of the auxiliary cell 130. Since the auxiliary cell 130 is independent of the optical path, And the convex dummy block 136 inwardly in one of the supports is made to be invisible, so that it can be advantageously operated in terms of the amount of the internal gas.

Therefore, the present invention allows the optical distance of the standard gas cell to be varied without being fixed, thereby allowing a plurality of standard gas cells to be maintained in a plurality of levels by maintaining a plurality of standard concentration gas concentrations, In addition, even if the gas concentration measurement range of the initial gas measuring instrument is specified, it is possible to linearly change the measuring range even during the measurement, so that the inspection / calibration time of the gas measuring instrument can be remarkably shortened Since it is possible to check and calibrate without having a standard gas cylinder around, it is convenient to move and use, and it is possible to improve work safety and reliability of the measuring device.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, Modification is possible. Accordingly, it is intended that the scope of the invention be defined by the claims appended hereto, and that all equivalent or equivalent variations thereof fall within the scope of the present invention.

1: Light source 2: Optical filter
3: gas sample cell 4,110: standard gas cell
5: photodetector 100: variable standard gas cell
111: first corrugated pipes 112a, 132a: gas inlet
112b, 132b: gas outlets 113a, 133a:
113b, 133b: Right side support 114: Guide
115a, 115b: Window 116: Linear motor
117: Linear motor drive unit 118:
120: connector 130: auxiliary cell
134: Pressure sensor 135: Temperature sensor
136: dummy block

Claims (9)

And a variable standard gas cell (100) capable of varying the optical distance of the standard gas cell (110) for measurement of the gas concentration of the optical gas meter to set a plurality of gas concentration correction values,
The variable standard gas cell (100)
And an auxiliary cell (130) connected to the standard gas cell (110) through a connection pipe (120) so as to maintain the same pressure as the internal pressure of the standard gas cell (110)
The variable standard gas cell (100)
The first corrugated tube 111 is freely adjustable in length and has a hollow body. The first corrugated tube 111 is installed on the optical path of the light emitted from the light source 1 and includes a gas inlet 112a and a gas outlet A standard gas cell 110 in which both ends of the first bell pipe 111 are sealed and supported by left and right support rods 113a and 113b respectively formed with the first bell pipe 112b;
A connection pipe 120 having one side connected to one of the gas inlet 112a and the gas outlet 112b of the standard gas cell 110; And
The left and right support rods 133a and 133b formed with the gas inlet 132a and the gas outlet 132b so as to allow the standard gas to flow in and out are formed in the second bell pipe 131, A pressure sensor 134 and a temperature sensor 135 for measuring the internal pressure and the temperature of the gas inlet 132a and the gas outlet 132b are provided at both ends of the second bell pipe 131, And an auxiliary cell 130 which is connected to the other side of the connection pipe 120 and maintains the same internal pressure as the standard gas cell 110 through the connection pipe 120. [ Reference value setting and measurement value correcting device of optical gas measuring instrument. delete delete The method of claim 1, wherein the variable standard gas cell (100)
A reflective gas detector in which the light source and the detector are located on the same side, a gas detector in the form of a light source, a gas cell and a detector arranged in a line, a light splitter for separating the light emitted from the light source into two or more, A gas detector of the type in which each detector is arranged and measured, or a gas meter of the type in which light emitted from a light source is separated into two or more by using a beam splitter and one detector is arranged at the end, Wherein the gas measurement unit is installed in a gas measurement section. The method of claim 1, wherein the standard gas cell (110)
One of the left and right support rods 113a and 113b is fixed to one end of the guide 114,
The other one of the left and right support rods 113a and 113b is supported so as to flow left and right along the guide 114 to vary the length of the first bell pipe 111,
The guide (114)
A scale for use in adjusting the gas concentration correction value of the standard gas cell 110 is displayed such that when the length of the first bell pipe 111 is extended to the maximum, And the gas concentration correction value of the standard gas cell (110) is set to display the minimum value (L "= 0) when the minimum value is compressed and the maximum value (L ' Measuring device. The method of claim 1, wherein the standard gas cell (110)
One of the left and right support rods 113a and 113b is fixed to one end of the linear motor 116,
The remaining one of the left and right support rods 113a and 113b is movably supported to the left and right along the linear motor 116 to vary the length of the first bell pipe 111,
The linear motor 116 is controllably connected to the linear motor driving unit 117 and the control unit 118 so that the length of the first bellows pipe 111 is automatically controlled by the control unit 118 A reference value setting and a measurement value correcting device of an optical gas measuring instrument. The method of claim 1, wherein the variable standard gas cell (100)
Wherein the gas concentration correction value of the standard gas cell (110) is set so as to maintain a maximum value when the initial standard gas is injected. The method of claim 1, wherein the standard gas cell (110)
And windows 115a and 115b are formed inwardly of the left and right support rods 113a and 113b in order to set the gas concentration in the cell to a zero state in a minimized volume state. A reference value setting device and a measuring value correction device of the measuring device. The apparatus of claim 1, wherein the auxiliary cell (130)
Wherein a convex dummy block (136) capable of positively controlling the amount of the internal gas is provided inside of any one of the left and right support rods (133a, 133b). Value correcting device.

Images