KR830000415Y1 - Alarm monitor device - Google Patents

Abstract

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Description

Alarm monitor device

1 is an explanatory diagram showing a conventional apparatus.

2 is an explanatory diagram showing an embodiment in which the alarm monitor device according to the present invention is used in an infrared analyzer.

In recent years, the pollution problem is complicated or serious, and the actual solution is also reported to become a big social problem.

For this reason, the pollutant discharged from automobiles, ships, chimneys, factory drains, etc. is determined by the law, and the allowable concentration or allowable load is determined.

For example, in the regulation of automobile emissions, the process-based passenger car regulation was imposed on the CO by 5.5% in 1970 in the "children" regulation, and in 1972, the regulation increased to 4.5%.

On the other hand, the emission limit of new cars was mandated in 1972 to prevent fuel evaporation, and in 1973, emission control of CO, HC, and NOX gas began.

While the above regulations are being promoted, the Environment Agency announced the 1975 regulation of tightening automobile emission regulations (the so-called Japanese version of the Dan pollution prevention act), and the average emissions for passenger cars are 89% of CO and 91% of HC. A reduction rate of 45% NOX and a reduction rate of 29% CO, 28% HC and 17% NOX for light buses and light trucks were compared to the current regulations.

In addition, the oil concentration in bilge drainage discharged from ships is regulated to less than 15 ppm by INCO (Intergovernmental Maritime Consultative Organization) regulation. As described above, the emission material that causes pollution cannot be discharged unless it is lowered below a certain standard value, but it is necessary to determine whether the material is below the regulation value by measuring the material with an analytical system.

For example, as a means for making judgment in CO regulation, the apparatus as shown in FIG. 1 was used conventionally.

Shown in this figure is an output meter which supplies a measurement sample to the measurement cell 2 of the infrared analyzer 1, amplifies the output signal from the detector 3 with an amplifier Amp, and is calibrated with a reference sample in advance. 4), the readings of the meter 4 are read out, and the output from the amplifier Amp is compared with the preset regulated output voltage Es with a comparator COMP so that the output E from the amplifier Amp is larger than the regulated output voltage Es. In this case, the relay 6 was energized to close the relay contact 7 and to operate the alarm device 8.

In the figure, reference numeral 9 denotes a sector, reference numeral 10 denotes a comparison cell, and L denotes a light source. However, if such regulation value is judged for a long time, accurate measurement and determination cannot be performed due to the drift of the infrared analyzer 1 and the amplifier Amp.

In order to perform correctly, calibration of zero point and span is necessary regularly, and efforts are required for calibration operation in the handling of the device. In addition, when the above calibration is performed by a reference sample, a zero point reference sample and a span reference sample are used. There were drawbacks such as requiring two samples of.

The object of the present invention is to provide an alarm monitor device capable of easily performing calibration and accurately determining a regulation value while eliminating errors due to drift of an analysis part and an amplification part. An embodiment shown in FIG. 2 will be described.

FIG. 2 is an explanatory view showing the case where the alarm monitor device of the present invention is used in an infrared analyzer for measuring carbon monoxide CO contained in a measurement sample. In the same drawing, reference numeral 11 denotes a light source as known as an infrared analyzer. L, the sensitivity checker 12, the sector 13, the comparison cell 14, the measurement cell 15, a detector 16 for emitting a signal voltage corresponding to the CO concentration in the measurement sample, and a zero sample or a measurement sample. It is comprised by the valve 17 etc. which switch selectively and send to the said measuring cell 15.

Amp is an amplifier of the amplifier 18 and amplifies the output signal sent from the detector 16.

Next, reference numeral 19 denotes a signal holding circuit (e.g., a holder amplifier or the like is used) and inputs the output signal of the amplifier Amp to the signal holding circuit 19 to hold this signal.

COMP is a comparator, a signal held by the signal holding circuit 19 and a sample measurement output signal output from the detector 16 and amplified by the amplifier Amp when the measurement sample is sent to the measurement cell 15 for analysis. In comparison, the relay 20 connected to the output terminal of the comparator COMP is energized when the sample measurement output signal is larger than the holding signal.

When the relay 20 is energized by the alarm lamp 21, the relay contact 23 is turned on to turn on the alarm lamp 21.

In addition, reference numeral 22 denotes a safety indicator lamp in which the relay contact 24 yops and shakes when the relay 20 is energized.

SW ₁ is a switch for operating the sensitivity checker 12, SW ₂ is a power switch of the lamps 21 and 22, SW ₃ is a signal holding circuit 19 for holding the output signal of the amplifier Amp. switch, and the switch SW _1, SW ₃ is adapted to on and off in conjunction.

Next, the operation of the above-described embodiment will be described.

First, the valve 17 is switched to send a zero sample into the measurement cell 15, and the switch SW ₁ is turned on to operate the sensitivity checker 12 of the regulation value equivalent signal.

At this time, the switch SW _{3 is} also turned on in conjunction. The infrared analyzer 11 emits a detection signal because zero sample is fed into the measurement cell 15, but the detection signal corresponds to the regulation value by the action of the sensitivity checker 12.

The detection signal from this detector 16 is amplified by the amplifier Amp and input to the signal holding circuit 19 (this signal voltage is now referred to as Es) to be held in the signal holding circuit 19.

The held signal voltage Es is input to one terminal b of the comparator COMP, and the output signal from the amplifier Amp (Es in this case) is also input to the other terminal a of the comparator COMP.

However, the comparator COMP is configured to output only when the signal voltage input to the other terminal a is larger than the signal voltage input to one terminal b. Therefore, in this case, the voltages input to both terminals are equal to Es. Because of this, the comparator COMP does not output.

Next, the switch SW ₁ is stopped and the operation of the sensitivity checker 12 is stopped. Then, the valve 17 is switched to supply a measurement sample into the measuring cell 15, and the infrared analyzer 11 analyzes and measures the detector ( Obtain the sample measurement output signal in 16). This amplified output signal is amplified by the amplifier Amp and input to one terminal a of the comparator COMP. (At this time, SW ₃ is off, so this input signal is not output to the signal holding circuit 19)

When the sample measurement output signal (signal voltage is E) is larger than the sustain signal voltage Es held by the signal holding circuit 19, the comparator COMP is output and the relay 20 is energized.

Therefore, the relay contact 24 is turned off, the safety display lamp 22 is turned off, and the relay contact 23 is turned on, so that the alarm lamp 21 is turned on. When the alarm lamp 21 is turned on, the operator can know that CO contained more than the regulated value in the measurement sample.

When the sensitivity checker 12 is not used, the reference voltage of the CO regulated value is sent into the measurement eye 15 instead of the zero sample to analyze the signal voltage in the signal holding circuit 19 as described above. Es can be maintained.

In addition, the regulation value equivalent signal voltage Es is applied to the signal holding circuit 19 and held in advance, and the measurement sample is then sent to the measurement cell 15 for analysis, thereby determining whether CO in the measurement sample exceeds the regulation value. You may also do so.

The present invention has the above-described configuration, and maintains the output signal from the measurement and analysis unit when analyzing the regulation value equivalent signal (and the equivalent thereof) or the regulation value reference sample as a signal holding circuit, and measures the measurement sample. The analyzer analyzes and compares the magnitude of the sample measurement output signal with the holding signal. Therefore, there is no need to perform zero point and span calibration as in the conventional apparatus. Because only need to measure and analyze once, the operability is greatly improved. In addition, two samples are not required as in the conventional apparatus, and only a zero point reference sample is sufficient.

In addition, immediately before analyzing the measurement sample, for example, the regulation reference sample may be analyzed by the measurement analysis unit, and the output signal of the measurement analysis unit may be maintained in the signal holding circuit, thus eliminating the need to consider the passage of time. As described above, errors due to drift of the analyzer and the amplifier can be eliminated, and accurate measurement and discrimination can be performed.

Claims (1)

In the comparator and alarm device for amplifying the output signal from the infrared analyzer and the detector, and the comparator and the alarm device, the regulation value equivalent signal or the output signal from the measurement analyzer 11 is sent to the signal holding circuit 19. The alarm monitoring device according to the measuring device, characterized in that the holding device is compared with the magnitude of the sample measuring output signal so that the alarm device 21 can be actuated according to the result.