RU2505804C1 - Method of air moisture content determination - Google Patents

Abstract

FIELD: instrumentation.

SUBSTANCE: proposed method consists in filling measuring vessel of known volume with dry air and weighing it. Then, measuring vessel is filled with air and weighed to record air temperature and pressure using measured magnitudes. Then, air moisture content d is defined by the formula:

g/kg dry, where m₁ is the weight of measuring vessel with dry air, g; m₂ is the weight of measuring vessel with analysed air, g; V is measuring vessel volume, liter; P_ap is analysed air barometric pressure, mm Hg; T_at is analysed air temperature, °C; g_n is specific weight of steam, g/l (g_n = 0.803 g/l); g_c is specific weight of dry air, g/l (g_c= 1.2928 g/l); P₀ is normal pressure, mm Hg (P₀=760 mm Hg); T₀ is normal temperature °C(T₀=273°C).

EFFECT: lower costs, higher precision and reliability.

1 dwg

Description

The invention relates to hygrometry, in particular to hygrometers measuring the relative humidity of the gas, and calibration of hygrometers without dismantling them from the object of operation.

There are various methods (methods) for measuring and reproducing gas humidity values presented in RMG 75-2004 (Recommendations on interstate standardization. GSI. Measurement of humidity of substances. Terms and definitions):

- sorption-gravimetric method - a gravimetric method for measuring the humidity of gases, based on the sorption method of separating moisture from gases;

- condensation-gravimetric method - a gravimetric method for measuring the humidity of gases, based on the condensation method of separating moisture from gases;

- condensation method - a method of measuring the dew point [hoarfrost], which consists in cooling the gas to the temperature of condensation (dew or hoarfrost) and measuring this temperature;

- and others.

The known method of direct weight determination of the moisture content of gases, which reduces to the absorption of moisture from a sample of a controlled gas by energy absorbers and determining its amount by increasing the weight of the absorbers. This method is highly accurate, but requires a lot of time (up to 30 hours).

The implementation of all these methods is characterized by a rather lengthy process of preparing and conducting measurements (several hours), as well as by the bulkiness of the required equipment, which limits their application capabilities (for example, for organizing the verification of working hygrometers without dismantling from the facility).

Closest to the claimed solution, taken as a prototype, is the "Method of complete absorption" (Berliner MA Measurements of humidity. - M .: Energy, 1973, pp. 349-351), based on weighing a certain volume of gas when passing it through a substance capable of absorbing water vapor, and assessing the change in the parameters of this substance as a result of complete absorption of moisture. To implement the method, a moisture absorption system is used to determine its mass and a system for measuring the volume of past gas. The analyzed gas is passed through three series-connected vessels having the form of U-shaped tubes filled with solid sorbents. To determine the mass of water vapor, the mass of the tubes is compared with sorbents before and after the flow of gas using accurate analytical scales. To measure the volume of gas, a system of two cylindrical chambers immersed in a thermostatic oil bath is used. The cameras fill up alternately. The dry gas mass is calculated by the number of chamber fillings, taking into account temperature and pressure.

The method of complete absorption can be considered as absolute, and its accuracy is limited by measurement errors (weighing the absorber, measuring the amount of gas) and the presence of impurities in the gas. The measurement process is lengthy and time-consuming, and therefore these methods are used only as laboratory ones. This method is used as the most accurate model for calibration, testing and calibration of hygrometers.

This method is expensive and time-consuming (more than 30 hours) to determine the humidity of the gases, and for its implementation a bulky device is used. In addition, when measuring with this method, it is necessary to dismantle the hygrometer from the facility and deliver it to a calibration laboratory.

The objective of the claimed solution is to reduce operating and time costs, increase the accuracy and reliability of measurements, as well as increase the convenience of the measurement process and the ability to maintain an electronic database of checks.

This goal is achieved due to the fact that in the known method for determining the moisture content of gases, which consists in direct weighing, according to the claimed solution, the measuring vessel of known volume is filled with dry air and weighed, then the measuring vessel is filled with test air and weighed, the temperature and pressure of the test air are recorded and, using the measured values, determine the moisture content of the test air according to the formula:

, г/кг сух.

, g / kg dry.

where m ₁ is the mass of the measuring vessel with dry air, g;

m ₂ is the mass of the measuring vessel with the test air, g;

V is the internal volume of the measuring vessel, liter;

R _willow - atmospheric pressure of the investigated air, mm Hg;

T _ive - the test temperature, ° C;

g _n is the specific gravity of steam, g / liter (g _n = 0.803 g / liter);

g _c is the specific gravity of dry air, g / liter (g _c = 1.2928 g / liter);

P ₀ - normal pressure, mm Hg (P ₀ = 760 mm Hg);

T ₀ - normal temperature ° C (T ₀ = 273 ° C);

The technical result of the claimed method and device is to reduce operating and time costs, due to the fact that in the proposed method instead of bulky equipment and a long operation, to determine the moisture content of air, a sealed measuring vessel, for example, a spherical shape made of light material of known volume V, is weighed , alternately filling it with dry and test air.

A comparative analysis of the claimed solution with the known, calls for: Comparison characteristic Prototype The proposed method Logistics 1. Precise lever analytical balance Electronic balance 2. Three glass vessels with chemical sorbents Not required 3. Two calibrated stainless steel cylindrical chambers and a massive thermostabilized bath Calibrated vessel made of duralumin or titanium. 4. Vacuum pump with pressure switch Vacuum pump (without pressure switch) 5. Compressor with compressed air drying system Not required 6. Refrigeration unit for oil bath Not required 7. Bypass line with shut-off valves Not required 8. Temperature and pressure meters Temperature and pressure meters Preparation time Up to 16 hours Not required Measurement duration Up to 30 hours Up to 3 minutes Results Processing Duration Up to 30 minutes Up to 3 minutes

The advantages of the proposed method:

a) to implement the method does not require expensive and bulky equipment;

b) the implementation of all operations of the proposed method takes several minutes;

c) the possibility of mathematical recalculation of the moisture content of air in any of its other hygrometric characteristics;

d) allows you to create a working standard (measuring vessel) for periodic verification of humidity measuring instruments operating at normal pressure, without dismantling them from the object of operation, in operating conditions;

d) the error of the proposed method (method) depends only on the errors of the used measuring instruments (pressure and temperature) and can have extremely small values.

The claimed solution is illustrated in the drawing.

The drawing shows a structural diagram of the implementation of the method. The circuit contains a measuring vessel 1, high-precision scales 2, dry air 3 (for example, a cylinder with dry air), an air evacuation device 4, an inlet valve (shut-off valve) 5, an outlet valve (shut-off valve) 6, a barometer 7, a thermometer 8, device for sampling the test air 9, the position 10 indicates the test environment.

To determine the moisture content of air, a sealed measuring vessel 1 is used (for example, spherical, duralumin or titanium) from any light material of known volume V, which is determined by the difference in the weights of the vessel without water and the vessel with water. The value of the volume of the measuring vessel is entered in its passport.

To calculate the moisture content of the test air, the following operations are carried out:

1. Determination of the total mass of the measuring vessel 1 with dry air.

The measuring vessel 1 with two valves, input 5 and output 6, is pumped with dry air 3 using a device for pumping air 4 (compressor or vacuum pump). Dry air can be obtained by drying the test air, i.e. passed through a zeolite or from a prepared container with dry air. Cranes 5 and 6 are alternately closed (first, valve 6 at the outlet of the vessel, then valve 5 at the inlet) and the measuring vessel 1 is weighed on an electronic balance 2 with the required error (for example, not more than ± 0.1 mg).

2. Determination of the total mass of the measuring vessel with the test air.

Both valves of the measuring vessel 1 open. The test air is pumped into the measuring vessel 1 using the device for pumping air 4 (compressor or vacuum pump). The taps 5 and 6 are closed alternately (first at the outlet of the vessel, then at its entrance), and the measuring vessel 1 is weighed on an electronic balance 2 with the required error (for example, not more than ± 0.1 mg).

3. Fix the pressure of the test air using a barometer 7.

4. Fix the temperature of the test air using a thermometer 8.

5. Calculate the moisture content of the test air according to the formula:

, г/кг сух.

, g / kg dry.

where m ₁ is the mass of the measuring vessel with dry air, g;

m ₂ is the mass of the measuring vessel with the test air, g;

V is the internal volume of the measuring vessel, liter;

R _willow - atmospheric pressure of the investigated air, mm Hg;

T _ive - the test temperature, ° C;

g _n is the specific gravity of steam, g / liter (g _n = 0.803 g / liter);

g _c is the specific gravity of dry air, g / liter (g _c = 1.2928 g / liter);

P ₀ - pressure under normal conditions, mm Hg (P ₀ = 760 mm Hg);

Т ₀ - temperature under normal conditions, ° С (Т ₀ = 273 ° С).

For a specific moisture content d (g / kg _dry ) of air, an empirical expression is obtained from the Id ramzin diagram to determine the relative humidity φ (%):

, %

%

The obtained humidity φ of the test air is compared with the readings of an attorney hygrometer φ _r and a conclusion is made about its metrological suitability.

For realization of the proposed method was manufactured hollow glass vial stoppered with two weighing 185.46 g weight measurement is carried out in the laboratory at a temperature of T = + _ive 23 ° C and atmospheric pressure P _ive = 756 mmHg with open plugs in order to avoid the influence of air density in the laboratory on the result of measurements of the mass of the vessel. The internal volume of the vessel was determined by the difference between the masses of the vessel with distilled water and empty:

V = 1.6127-0.18546 = 1.4272 L

m _containers = 185.46 g and the internal volume of the vessel V = 1.427 l was entered in the passport.

The vessel was filled with dry air and weighed, which amounted to m ₁ = 187.1584 g. This mass consists of the sum of the tare and air masses minus the mass corresponding to the buoyancy force of Archimedes m _arch :

187,1584 = 185,46 + g _c · V ₀ -m _architect

where V ₀ is the volume of gas reduced to normal conditions.

The vessel was filled with test air, an exemplary thermohygrometer showed a relative humidity of 47.6%. The vessel was weighed on an electronic balance with a resolution of 0.1 mg. The mass was m ₂ = 187.1500 g. The mass difference Δ _m :

where m _c is the mass of dry air;

m _x is the mass of the studied air;

g _x is the specific gravity of the test air.

Therefore, the mass of the studied air in the vessel

m _x = g _c · V ₀ -Δm = 1.2928 · 1.3092-0.0084 = 1.6841

The mass m _{x is the} sum of the mass of dry air and the mass of water vapor, taking into account the volumes occupied, i.e.

m _x = g _x · V ₀ = m _s + m _n = g _c (V ₀ -V _n ) + (g _n · V _n ) = 1.6841 g

The vapor volume V _n is

Moisture content of test air

At t ° = + 23 ° C, this moisture content corresponds to a relative humidity of φ% = 47.63% (I-d Ramzin diagram)

To increase the sensitivity of the proposed method, the measuring vessel should be made larger capacity.

The claimed method can be used to verify working hygrometers designed to measure relative humidity in the operating conditions of their operation (without dismantling from the facility). In addition, it can be used to determine the moisture content of any gases, with the corresponding refinement of the coefficients of the components of the mathematical apparatus.

Claims (1)

A method for determining the moisture content of air, which consists in direct weighing, characterized in that the measuring vessel of known volume is filled with dry air and weighed, then the measuring vessel is filled with test air and weighed, the temperature and pressure of the test air are recorded and, using the measured values, the moisture content d of the test is determined air according to the formula:

, g / kg dry.
where m ₁ is the mass of the measuring vessel with dry air, g;
m ₂ is the mass of the measuring vessel with the test air, g;
V is the internal volume of the measuring vessel, liter;
R _willow - atmospheric pressure of the investigated air, mm Hg;
T _ive - the test temperature, ° C;
g _n is the specific gravity of steam, g / liter (g _n = 0.803 g / liter);
g _c is the specific gravity of dry air, g / liter (g _c = 1.2928 g / liter);
P ₀ - normal pressure, mm Hg (P ₀ = 760 mm Hg);
T ₀ - normal temperature ° C (T ₀ = 273 ° C).