RU2761133C2 - Method for adjusting a nephelometer photometer - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention relates to the field of photometry and pertains to a method for adjusting a nephelometer photometer. The method consists in measuring the value of light scattering of clean air at a certain pressure in the aerosol chamber of the nephelometer photometer, determining the result of measurement, and adjusting the nephelometer photometer based on the results of measurement. The value of light scattering of clean air in the aerosol chamber of the nephelometer photometer is measured at a pressure no greater than 0.667 kPa. The current value of atmospheric pressure is then determined and the nephelometer photometer is adjusted according to the reference current value determined depending on the actual atmospheric pressure at the time of adjustment and the own light scattering of the aerosol chamber of the nephelometer photometer.

EFFECT: increase in the accuracy and reduction in the complexity of adjusting a nephelometer photometer.

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Description

The proposed invention relates to the field of applied optics and photometry, namely, to methods of metrological support of aerosol photometers - nephelometers and can be used when adjusting aerosol photometers - nephelometers used in various branches of the national economy, science and technology.

The closest analogue of the claimed invention is a method for adjusting aerosol nephelometers according to AC SU No. 576516, which consists in the fact that in order to increase the accuracy of adjusting the sensitivity of the nephelometer, the nephelometer is adjusted by the difference of two measurements when air with atmospheric pressure and air with a pressure value different from atmospheric is passed through the chamber. ... First, with an arbitrarily chosen sensitivity of the photometer-nephelometer and passing clean air of atmospheric pressure through its aerosol chamber, the readings of the photometer-nephelometer are taken (measurement is made). Then, without changing the sensitivity of the nephelometer photometer, clean air with a changed pressure (different from atmospheric) is passed through its aerosol chamber, while the readings of the nephelometer photometer are again taken (a second measurement is made). After that, according to the difference between the results of the first and second measurements, the control value of the current corresponding to light scattering is determined and the control value of the current is used to adjust the photometer-nephelometer. However, this method does not take into account the individual parameters of the photometer-nephelometer, namely the own scattering of the aerosol chamber, and for each device (photometer-nephelometer) it has an individual value. Therefore, the method does not allow accurate adjustment of the nephelometer photometer, and, therefore, to ensure the required measurement accuracy when working with the device (nephelometer photometer). Determined empirically, the accuracy of the adjustment of the photometer - nephelometer according to this method is in the range from 20% to 25%.

The objective of the present invention is to improve the accuracy of adjustment of the nephelometer photometer.

The problem is solved by the fact that in the known method, which consists in measuring the amount of light scattering of clean air at a certain pressure in the aerosol chamber of the photometer - nephelometer, determining the measurement result and adjusting the photometer-nephelometer according to the measurement results, the amount of light scattering of the aerosol chamber of the photometer-nephelometer is measured at the clean air in it under a pressure of no more than 0.667 kPa. Then, the current value of atmospheric pressure is determined using the barometer, and the photometer - nephelometer is adjusted according to the control current value determined by the formula:

where I _to - the control value of the current, μA;

Р - actual atmospheric pressure at the moment of adjustment of the nephelometer-photometer, kPa;

I _{p -} intrinsic light scattering of the aerosol chamber of the photometer-nephelometer, μA.

The essential distinguishing features of the proposed invention from the prototype are:

- measuring the amount of light scattering of the aerosol chamber of the photometer - nephelometer when there is clean air in it under a pressure of no more than 0.667 kPa (5 mm Hg), i.e. under vacuum;

- determination of the current value of atmospheric pressure;

- determination of the control value of the current for adjustment according to the above formula.

All of the above set of distinctive features is necessary and sufficient to achieve the set task and technical result. The adjustment accuracy of the photometer - nephelometer according to the proposed method, determined empirically, is no more than 15%.

Examples of the method

Example 1. The first photometer, a nephelometer, was accepted for adjustment. Using a vacuum pump, the air was evacuated from the aerosol chamber of the nephelometer photometer to a value of no more than 0.667 kPa (5 mm Hg). Determined the value of the current corresponding to the eigenvalue of light scattering of the aerosol chamber of the photometer - nephelometer, which was 20 μA.

The current atmospheric pressure was measured at the place where the nephelometer photometer was installed. The current atmospheric pressure was 101.325 kPa (760 mm Hg).

The control value of the current was calculated using the formula:

The resulting value Ik = 116.9 μA is set on this nephelometer photometer as a reference value.

A second photometer, a nephelometer, was accepted for adjustment. Using a vacuum pump, the air was evacuated from the aerosol chamber of the nephelometer photometer to a value of no more than 0.667 kPa (5 mm Hg). Determined the value of the current corresponding to the eigenvalue of light scattering of the aerosol chamber of the photometer - nephelometer, which was 30 μA.

The current atmospheric pressure was measured at the place where the nephelometer photometer was installed. The current atmospheric pressure was 101.325 kPa (760 mm Hg).

The control value of the current was calculated using the formula:

The resulting value Ik = 126.7 μA is set on this (second) nephelometer photometer as a reference value.

As a result, these two different nephelometer photometers installed in one place (under conditions of the same atmospheric pressure), having different control values of Ik, are configured for operation and will allow measurements of the mass concentration of aerosols pumped through the aerosol chambers of the first and second nephelometer photometers with the same accuracy no more than 15%.

This example has industrial applicability, since in the production of anti-aerosol filters and absorbing gas mask boxes, all produced anti-aerosol filters and absorbing gas mask boxes are monitored for the permeability of oil mist (aerosol), for which several nephelometer photometers are used simultaneously.

Example 2.

A photometer - a nephelometer was accepted for adjustment. Using a vacuum pump, the air was evacuated from the aerosol chamber of the nephelometer photometer to a value of no more than 0.667 kPa (5 mm Hg). Determined the value of the current corresponding to the eigenvalue of light scattering of the aerosol chamber of the photometer - nephelometer, which was 20 μA. The current atmospheric pressure was measured at the place where the nephelometer photometer was installed. Current atmospheric pressure is 101.325 kPa (760 mm Hg).

The control value of the current was calculated using the formula:

The resulting value Ik = 116.9 μA is set on this nephelometer photometer as a reference value.

Further, the operation of the photometer-nephelometer began to control the quality of the released anti-aerosol filters and absorbing boxes of gas masks according to the permeability of oil mist. After 24 hours, the atmospheric pressure of the ambient air changed and amounted to 98.658 kPa (740 mm Hg). The control value of the current was calculated using the formula:

The resulting value Ik = 113.8 μA is set on this nephelometer photometer as a reference value. This reference value will allow maintaining the accuracy of the nephelometer-photometer no more than 15%.

Example 3.

The first photometer, a nephelometer, was accepted for adjustment. Using a vacuum pump, the air was evacuated from the aerosol chamber of the nephelometer photometer to a value of no more than 0.667 kPa (5 mm Hg). Determined the value of the current corresponding to the eigenvalue of light scattering of the aerosol chamber of the photometer - nephelometer, which was 20 μA.

The current atmospheric pressure was measured at the place where the nephelometer photometer was installed. The current atmospheric pressure was 101.325 kPa (760 mm Hg).

The control value of the current was calculated using the formula:

The resulting value Ik = 116.9 μA is set on this nephelometer photometer as a reference value.

A second photometer, a nephelometer with an installation site at a remote site, was accepted for adjustment. Using a vacuum pump, the air was evacuated from the aerosol chamber of the nephelometer photometer to a value of no more than 0.667 kPa (5 mm Hg). Determined the value of the current corresponding to the eigenvalue of light scattering of the aerosol chamber of the photometer - nephelometer, which was 30 μA.

The current atmospheric pressure was measured at the place where the nephelometer photometer was installed. The current atmospheric pressure was 98.658 kPa (740 mm Hg). The control value of the current was calculated using the formula:

The resulting value Ik = 123.3 μA is set on this (second) nephelometer photometer as a reference value.

As a result, two different nephelometer photometers installed in different places (under conditions of different atmospheric pressure), having different control values of Ik, are configured for operation and allow measurements of the mass concentration of aerosols pumped through the aerosol chambers of the first and second nephelometer photometers with the same accuracy no more than 15%.

Thus, the proposed method improves the accuracy of the adjustment of the nephelometer photometer used to measure the mass concentration of aerosols pumped through the aerosol chamber in different cases of its use, namely:

- the use of several nephelometer photometers at the same time, since during the production of anti-aerosol filters and absorbing gas mask boxes, all released anti-aerosol filters and absorbing gas mask boxes are monitored for the permeability of oil mist (aerosol);

- preservation of the adjustment accuracy when the atmospheric pressure changes after a while in the case of using a photometer - nephelometer to control the quality of the released anti-aerosol filters and absorbing gas mask boxes according to the permeability of oil mist; - maintaining the accuracy of the adjustment of two photometers - nephelometers installed in different places (under conditions of different atmospheric pressure).

In addition, the proposed tuning method is less labor-intensive than the prototype, because only one measurement is carried out.

Claims (5)

A method for adjusting a photometer-nephelometer, which consists in measuring the amount of light scattering of clean air at a certain pressure in the aerosol chamber of the photometer-nephelometer, determining the measurement result and adjusting the photometer-nephelometer according to the measurement results, characterized in that the amount of light scattering of the aerosol chamber of the photometer-nephelometer is measured when the pressure of clean air in it is not more than 0.667 kPa, then the current value of atmospheric pressure is determined and the photometer-nephelometer is adjusted according to the control value of the current determined by the formula:

where I _to - the control value of the current, μA; Р - actual atmospheric pressure at the moment of adjustment of the nephelometer-photometer, kPa; I _p - intrinsic light scattering of the aerosol chamber of the photometer-nephelometer, μA.