JPH0114916Y2 - - Google Patents

Description

[Detailed description of the invention] [Technical field to which the invention pertains] The present invention relates to a gas concentration measuring device that checks the life of a gas concentration sensor during a calibration operation and displays the result.

[Conventional technology]

A conventional oxygen concentration measuring device includes a galvanic cell, a variable gain amplifier that amplifies the output signal, and a display section that linearizes the output of the amplifier and displays the oxygen concentration.

Because these oxygen concentration measurement devices are highly sensitive, they are often used to monitor oxygen concentration in oxygen tents (medical use) and to monitor oxygen deficiency in working environments such as various construction sites and factories (industrial use). There is.

Incidentally, the galvanic cell has a limited lifespan like a general battery, and its characteristics change over time (this appears as a decrease in output and deterioration in linearity). Therefore, it is necessary to perform calibration periodically or as needed to compensate for changes in characteristics and maintain measurement accuracy. This calibration is performed by using calibration air or pure oxygen, manipulating the volume of the variable gain amplifier, and setting a new calibration coefficient.

However, with conventional oxygen concentration measuring devices,
When the galvanic cell reaches the end of its lifespan, it can no longer be compensated for by the above-described volume operation. That is, only in this situation does it become clear that the galvanic cell has reached the end of its lifespan. For this reason, it is difficult to properly prepare the galvanic cell, which poses a problem in terms of maintenance.

[Purpose of invention]

The present invention has been made in view of these points, and its purpose is to provide a gas concentration measuring device with excellent maintainability.

[Structure of the idea]

The gas concentration measuring device of the present invention that achieves the above object includes a gas concentration sensor and a signal processing section that inputs the output signal of the sensor, performs predetermined calculations, and outputs a concentration signal, and includes , has a predetermined upper limit value, a first lower limit value, and a second lower limit value smaller than the first lower limit value, and when the concentration signal is between the upper limit value and the first lower limit value during a calibration operation, a calibration signal is generated. a signal processing unit that outputs a calibration signal and a sensor life notice display signal when the value is between the first and second lower limits, and a sensor life display signal when the value is below the second lower limit; and a display section that inputs signals and displays information based on the contents of each signal.

[Example of idea]

The present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing an embodiment of the present invention. The oxygen concentration measurement device includes a galvanic cell 1 and an A/D that converts the cell output signal into a digital signal.
Sensor unit 3 consisting of a conversion circuit, CPU 4, and RAM
5. A signal processing unit 9 consisting of a ROM 6, etc., a microcomputer 7 and a calibration command switch 8;
It has a display section 12 consisting of a drive circuit 10 and a digital display 11 having a stroke element configuration. The RAM 5 of the signal processing unit 9 stores calibration coefficients calculated based on a program stored in the ROM 6, which will be described later. Also, the ROM6 is the sensor section 3.
a program that inputs the output signal of , calculates it using the calibration coefficient, and outputs the concentration signal V _D ;
As shown in the figure ( _the horizontal axis shows the concentration signal), the predetermined _first upper limit V ₁ and a first lower limit value V ₂ , and a second lower limit value V ₃ smaller than the first lower limit value V ₂ , and a calibration point CP ₂
(100vol% _O2 when calibrating with pure oxygen
A predetermined second upper limit value V ₄ and a third lower limit value V ₅ are provided before and after the concentration signal V _D
corresponds to the following relationship, and the calibration signal V _C , the sensor life notice display signal V _P or the sensor life display signal V _E
Contains a program that outputs .

V ₂ ≦V _D ≦V ₁ or V ₅ ≦V _D ≦V ₄ → Calibration signal V _C V ₃ ≦V _D ＜V ₂ → Calibration signal V _C sensor life notice signal V _P V _D ＜V ₃ or V ₁ <V _D <V ₅ or V ₄ <V _D →Sensor life display signal V _EFurthermore , the ROM6 determines whether or not a calibration operation is required before or during measurement, and determines whether or not a calibration operation is required. , stores a program that outputs a calibration request display signal _VF .

In the above configuration, for measurement, as shown in FIG. 3A, when the power is turned on (20), the signal processing section 9 checks whether the calibration coefficient is stored in the RAM 5 (21), If not stored,
Output the calibration request signal V _F and display “CAL” on the display 11
(22). On the other hand, as shown in Figure 3B,
During measurement (23, 24, 25), when the calculation result in the signal processing section 9 becomes a concentration value of 103 vol% O ₂ or more (26), the signal processing section 9 outputs a calibration request signal V _F and outputs "CAL". ” is displayed on the display 11. When calibration is performed using calibration air or pure oxygen in accordance with this calibration request display, the signal processing section 9 operates based on the flowchart shown in FIG. 4. That is, when the calibration air is introduced into the galvanic cell 1 and the switch 8 is turned on (30), the signal processing section 9 takes in the output signal of the sensor section 3 (31), and the concentration signal V _D reaches the first upper limit value V. ₁ and the first and second lower limit values V ₂ and V ₃ as boundaries (32,
33, 34). Then, the concentration signal V ₃ satisfies V ₂ ≦V _D ≦V ₁
When , the calibration calculation is performed as an air point and the calibration signal V _C
Display “21.o” (35, 36). Also, V ₃ ≦V _D
When < _V2 , a calibration calculation is performed as an air point, and the display "21.o" is displayed by the calibration signal V _C and the one-character stroke element is flashed by the sensor life notice display signal (37, 38). Furthermore, when V _D <V ₃ , the sensor life display signal indicates "End" (39).

On the other hand, in the calibration operation using pure oxygen, the signal processing unit 9 determines that the concentration signal V _D is the second upper limit value V ₄ ,
It is determined which of the ranges whose boundaries are the third lower limit value V ₅ and the first upper limit value V ₁ it belongs to (32, 40, 41).
Then, when the concentration signal V _D satisfies V ₅ ≦V _D ≦ V ₄ ,
Calibration calculation is performed as ₂ points of 100vol%O, and the display is “100.o” using the calibration signal V _C (42, 43), V ₁ < V _D < V ₅
Or, when V ₄ < V _D , display “End” using the sensor life display signal (44).

Therefore, when one stroke element flashes during the calibration operation, a new galvanic cell 1
By preparing the following, there will be no interruption of measurement due to the life of the galvanic cell.

It should be noted that the present invention is not limited to the above-mentioned embodiments, and for example, either calibration air or pure oxygen may be used as the calibration gas. Even in the calibration using pure oxygen, if you want to obtain an indication by the sensor life notice signal, the fourth lower limit value (which is smaller than the third lower limit value _V5 ) corresponding to the second lower limit value _V3 at the calibration point _CP1 is used. value)
All you have to do is set . Further, the measuring device may be used for components other than oxygen as the component to be measured, and the sensor section may be constructed from a sensor other than a galvanic cell.

[Effect of idea]

As explained above, according to the gas concentration measuring device of the present invention, the service life of the gas concentration sensor is checked during the calibration operation and the result is displayed, which facilitates maintenance and avoids interruption of measurement due to the service life of the sensor. It will no longer cause any trouble.

[Brief explanation of the drawing]

FIG. 1 is a configuration diagram showing an embodiment of the present invention, FIG. 2 is an explanatory diagram of the relationship between upper and lower limit values for obtaining a display signal, FIG. 3 is an explanatory diagram of the operation of a calibration request, and FIG.
The figure is an explanatory diagram of the calibration operation. 3...Sensor section, 9...Signal processing section, 12...
Display section.

Claims (1)

[Scope of utility model registration request] A gas concentration sensor, and a signal processing unit that inputs an output signal of the sensor, performs a predetermined calculation, and outputs a concentration signal, and includes a predetermined upper limit value, a first lower limit value, and a predetermined upper limit value and a first lower limit value before and after a calibration point. 2nd value smaller than 1 lower limit
has a lower limit value, and during a calibration operation, the concentration signal is
When the value is between the upper limit and the first lower limit, a calibration signal is sent; when the value is between the first and second lower limit, a calibration signal and a sensor life notice display signal are sent; and when the value is below the second lower limit, a sensor life display signal is sent. What is claimed is: 1. A gas concentration measuring device comprising: a signal processing section that outputs each signal; and a display section that receives signals from the signal processing section and displays a display based on the content of each signal.