RU2659462C1 - Device for determining gas volume involved in the mass-exchanging process in the gas-liquid system - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: device for determining gas volume involved in the mass-exchanging process in the gas-liquid system. Invention relates to device for determining gas volume involved in the mass-exchanging process in the gas-liquid system for calculating the rate of the mass-exchanging process, on the basis of which the mass-transfer coefficient used in the development of new and modernization of known industrial mass-exchanging apparatuses is calculated. Device for determining gas volume involved in the mass-exchanging process in the gas-liquid system comprises a container for the gas to be examined and a container for the liquid to be examined, which are made in the form of cylinders with a measuring scale. Container for the gas and container for the liquid are provided with a movable piston. Container the liquid is connected to the container for the gas from the bottom.

EFFECT: simplified device, allowing to determine gas volume involved in the mass-exchanging process in the gas-liquid system.

1 cl, 1 dwg, 1 tbl

Description

The invention relates to a device for determining the volume of gas involved in a mass transfer process in a gas-liquid system for calculating the speed of a mass transfer process, based on which the mass transfer coefficient used to develop new and modernize known industrial mass transfer devices is calculated.

The closest in technical essence is a device for determining the rate of absorption of gas by a liquid absorber by determining the volume of gas involved in the mass transfer process in the gas-liquid system, and the time during which the mass transfer process is carried out, including a thermostatically controlled liquid container, two graduated glass cylinders for test gas (gas tanks), which are connected to a thermostatically controlled liquid tank, two pressure gauges, two rheometers, two refrigerators They are connected to graduated glass cylinders, while the graduated glass cylinders are equipped with equalization flasks driven by a common rod with a winch.

The mass transfer process is carried out in a thermostatically controlled liquid tank (tank for the test liquid), passing the test gas from the gas tank into the liquid tank with a strictly defined constant speed, which is measured using a rheometer, and at the same pressure, a constant value of which is achieved using equalization bottles.

The gas is passed through the absorption solution (test liquid) of the thermostatically controlled tank until the gas volume remains unchanged when passing from one graded glass cylinder to another, and the gas volume is fixed on the graduated glass cylinder measuring scale as the difference between the initial and final gas volumes. The amount of gas involved in the mass transfer process per unit time determines the speed of the process (SU Copyright Certificate No. 289337, IPC1 G01N 13/00, 1971).

The disadvantages of this object is a technologically complex and labor-consuming device to manufacture, the complexity of determining the volume of gas involved in the mass transfer process, which is determined by providing a strictly defined constant flow rate of the test gas into a thermostatically controlled liquid tank and ensuring a constant pressure in the gas-liquid system, which reaches by moving synchronized equalization tanks with graduated glass cylinders using traction by rashchenija winch.

The objective of the invention is to simplify the device, which allows to determine the volume of gas involved in the mass transfer process in the gas-liquid system.

The technical problem is solved by a device for determining the volume of gas involved in the mass transfer process in a gas-liquid system, including a container for a test gas and a container for a test liquid, made in the form of cylinders with a measuring scale, according to the invention, the gas container and the liquid container are equipped with a movable piston while the liquid tank is connected to the gas tank from the bottom.

The solution to the technical problem allows us to simplify the device, which allows to determine the volume of gas involved in the mass transfer process in the gas-liquid system.

A device for determining the volume of gas involved in the mass transfer process in a gas-liquid system (Fig. 1) includes a container for the test liquid 1 and a container for the test gas 2, which are made in the form of cylinders with a measured scale, a measured scale of the tank for gas 3 and the measuring scale of the liquid tank 4, the gas tank and the liquid tank are provided with a movable piston, the mobile piston of the gas tank 5, the movable piston of the liquid tank 6, while the liquid tank 1 is connected to the gas tank 2 from the bottom.

Example 1

The claimed device operates as follows. The test fluid is supplied to the fluid container 1, the test gas is supplied to the gas container 2, the volume of the supplied gas is determined by the measuring scale of the gas container 3, the volume of the supplied fluid is determined by the measuring scale of the liquid container 4, the liquid container 1 is connected to the container for of gas 2 from the bottom, the test liquid from the liquid tank 1 is supplied to the lower part of the gas tank 2 using a movable piston 6, i.e. the mass transfer process is carried out in a gas tank, supplying the test liquid with a movable piston 6 from the liquid tank 1 to the gas tank 2, the start time of the mass transfer process is fixed. The mass transfer process is carried out at the same pressure, a constant value of which is achieved by automatically moving the movable piston 5 of the gas tank 2.

At the end of the mass transfer process, the position of the movable piston 5 on the measuring scale 3 of the gas tank 2 and the end time of the mass transfer process when the volume of gas in the gas tank remains constant are fixed. By changing the gas volume during the phase contact time, the numerical value of the gas volume participating in the mass transfer process is determined.

The volume of gas involved in the mass transfer process in the gas-liquid system is determined in the device according to the claimed object, where CO _{2 is} taken as the test gas, and 0.1N alkali solution - NaOH is taken as the test liquid.

The volume of CO ₂ gas supplied is determined by the measuring scale 3 of the gas tank 2, in this case it is 160 cm ³ (0.00016 m ³ ), the volume of the supplied liquid 0.1N alkali solution - NaOH is determined by the measuring scale 4 of the liquid tank 1 , the liquid tank 1 is connected to the gas tank 2 from the bottom. The liquid under investigation from the liquid container 1 in an amount of 10 cm ³ (0.00001 m ³ ) is supplied to the lower part of the gas container 2 using a movable piston 6, i.e. the mass transfer process is carried out in a gas tank. The time of the beginning of the mass transfer process is recorded. The mass transfer process is carried out at the same pressure, a constant value of which is achieved by automatically moving the movable piston 5 of the gas tank 2.

The end of the mass transfer process is judged by the volume of gas in the gas tank when its volume remains constant. The position of the movable piston 5 on the measuring scale 3 of the gas tank 2 is fixed, in this case it is 10 cm ³ (0.00001 m ³ ), and the duration of the mass transfer process (absorption of carbon dioxide by alkali solution) is determined as the difference in the stopwatch readings recorded at the end and the beginning of the mass transfer process.

The numerical value of the volume of gas involved in the mass transfer process is determined by the change in gas volume, ΔV _t = V _n -V _k , i.e. 160 cm ³ minus 10 cm ³ is equal to 150 cm ³ (0.00015 m ³ ) during the phase contact time, in this case, equal to 270 s.

By the amount of gas involved in the mass transfer process per unit time, the speed of the mass transfer process is calculated by the equation

where M is the speed of the mass transfer process, kg / s;

ΔV _t = V _n -V _k is the change in gas volume in the gas-liquid system from the gas volume at the beginning of the mass transfer process V _n to the gas volume V _k at the end of the mass transfer process, m ³ ;

Δt is the time interval from the beginning of the mass transfer process to the end of the mass transfer process in the gas-liquid system, s;

ρ is the gas density at the temperature of the mass transfer process, kg / m ³ .

The speed of the studied mass transfer process in the gas-liquid system using the inventive object is 10.94⋅10 ^-7 kg / s.

The numerical value of the speed is obtained from the calculation according to equation (1)

M _{= (ΔV t / Δt) ⋅ρ} = (0,00015 m ^3/270) ⋅1,97 kg / m ³ = 10,94⋅10 ^-7 kg / s,

where ρ is 1.97 kg / m ³ is the density of СО ₂ at the temperature of the process (in this case, at 20 ° C).

To compare the data on the speed of the mass transfer process obtained using the device according to the claimed object and the prototype in the presence of the same test gas and the same test liquid, calculate the mass transfer coefficient Ku, which is equal to the amount of gas involved in the mass transfer process per unit time, referred to the unit surface area of the contact phase, kg / s /m ² .

The mass transfer coefficient is calculated by the equation

where M is the speed of the mass transfer process, kg / s, which is determined in the inventive device and in the device of the prototype;

F is the surface area of the phase contact in the gas-liquid system, m ² .

The surface area of the phase contact in the gas-liquid system using the inventive device is calculated by the equation

where D is the diameter of the tank for gas of the claimed device, m ² .

The surface area of the phase contact in the gas-liquid system according to the prototype is calculated by the equation

where Vzh - the volume of the absorption solution (test fluid) in the device according to the prototype, m ³ ;

α is the specific contact surface of the phases, m ² / m ³ .

The specific contact surface of the phases in the gas-liquid system according to the prototype is determined by statistical processing of photographs, on the basis of which the average volume-surface diameter of the bubbles d _p and the gas content of the layer ϕ are determined, after which the specific contact surface of the phases is calculated by the equation

where ϕ is the gas content of the layer of the investigated fluid;

d _p - average volumetric-surface diameter of the bubbles

(Ramm V.M. Gas Absorption. - M.: Chemistry, 1976, p. 156).

The determination of the specific contact surface of the phases is associated with the processing of photographs, which is a laborious work.

The numerical value of the mass transfer coefficient is obtained from the calculation according to equation (2)

Ku = M / F = 10.94⋅10 ^-7 kg / s / 0.001256 m ² = 8.71⋅10 ^-4 kg / s m ²

where M is the speed of the mass transfer process, kg / s;

F is the surface area of the phase contact in the gas-liquid system, m ² .

Examples 2 and 3 using the device of the prototype and the claimed object are made analogously to example 1.

Data on Ku - mass transfer coefficient of the mass transfer process, kg / s⋅m ² , obtained on the basis of determining the volume of gas involved in the mass transfer process in the gas-liquid system, using the prototype device and the claimed object, are shown in table 1.

As can be seen from table 1, the average values of K _y - mass transfer coefficient of the mass transfer process, kg / s ² obtained using the device of the prototype and the claimed object are close to each other, but the data on examples 1, 2 and 3, obtained using devices according to the claimed object, more stable than using a device according to the prototype.

In addition, the prototype device is technologically complex and laborious to manufacture, determining the volume of gas involved in the mass transfer process is time consuming due to the need to ensure a strictly defined constant flow rate of the test gas into the liquid tank and to ensure a constant pressure in the gas-liquid system achieved by moving equalization tanks using traction by rotating the winch.

The numerical value of the mass transfer coefficient of the mass transfer process Ku is used in the development of industrial mass transfer devices, for example, to calculate the required surface area of the phase contact in order to ensure a given productivity of the device, which is equal to M _a - the amount of gas involved in the mass transfer process per unit time, according to the equation

where F _a - surface area of the contact of the phases (mass transfer surface in the developed apparatus - the absorber), m ² ;

M _a - the given performance of the apparatus, kg / s;

Ku - mass transfer coefficient of the mass transfer process, kg / s⋅m ² ;

Δ Yep is the average driving force of the mass transfer process

(Pavlov K.F., Romankov P.G., Noskov A.A. Examples and tasks in the course of processes and apparatuses of chemical technology. - L .: Chemistry, 1987, p. 291).

Thus, the claimed device for determining the volume of gas involved in the mass transfer process in the gas-liquid system, reliable and simple in design, based on the obtained volume of gas involved in the mass transfer process in the gas-liquid system, stable values of the speed of the mass transfer process in the system are obtained gas - liquid, kg / s, and based on the speed of the mass transfer process calculate the mass transfer coefficient, kg / s /m ² , used in the development of new and modernization of well-known industrial mass transfer apparatus comrade

Claims (1)

A device for determining the volume of gas involved in the mass transfer process in a gas-liquid system, including a container for a test gas and a container for a test liquid, made in the form of cylinders with a measuring scale, characterized in that the gas tank and the liquid tank are equipped with a movable piston, wherein the liquid tank is connected to the gas tank from the bottom.