RU44388U1 - GAS DENSITY ANALYZER - Google Patents

Abstract

The utility model relates to the field of analytical technology, namely, to laboratory means of measuring the density of gases.

The gas density analyzer contains a miniature turbulent constriction device connected through a tee to a chamber for compression of the analyzed gas and with a differential meter including a positive camera made flow-through, equipped with a device for fixing the end of measurements and connected through the inlet fitting to the line of the analyzed gas, and through the outlet fitting - with a tee and a “minus” camera equipped with a device for fixing the beginning of measurements and connected to the atmosphere, while devices for fixing the beginning and end of measurements are connected s with an electronic stopwatch.

In addition, the analyzer contains a pneumatic tumbler connected to the outlet of the miniature turbulent constriction device and a syringe, the inlet of which is connected to the outlet of the chamber for gas compression, made in the form of a spiral from a thin-walled tube. The differential meter is divided into “plus” and “minus” chambers with a metal membrane, and the devices for starting and ending measurements are made in the form of needles, the tips of which are turned towards two membrane surfaces with the possibility of forming two pressure difference-controlled electrical contacts. The body of the syringe is equipped with a fitting, the location of which is due to the possibility of the formation of a flow chamber from the syringe with the piston extended as much as possible.

Description

The utility model relates to the field of analytical technology, namely, to means for measuring gas density

A known gas density analyzer (Kirillin V.A., Sheindlin A.E. Study of the thermodynamic properties of substances; M-L; Gosenergoizdat, 1963 - p.176-177), containing a two-pipe liquid differential pressure gauge, the measuring tube of which is equipped with a diaphragm and devices for fixing the beginning and the end of measurements and an electronic stopwatch. The density measurement by the analyzer reduces to determining the expiration time of a constant volume of the analyzed gas displaced by the gate fluid of the differential pressure gauge through the diaphragm opening.

The disadvantage of the analyzer is the complexity of the measurements, which is associated with the need to carry out operations to clean the analytical chamber from traces of gas remaining from the previous measurement (auxiliary devices are used for this) and low (0.5-1%) measurement accuracy (Kivilis S.S. Density meters . M., Energy; 1980 - p. 166-168).

The closest in technical essence of the known laboratory gas density analyzers to the proposed one is a gas density analyzer (RF Patent No. 2094768. Gas density analyzer. / Ilyasov LV Bull. No. 30.1997) containing a miniature turbulent constriction device connected via a tee to the camera for compression of the analyzed gas and with a transmitter, including a “positive” camera, made flow-through, equipped with a device for fixing the end of the measurements and connected through the inlet fitting to the line of the analyzed gas, and through yhodnoy fitting - with a tee and "minus" chamber provided with fixing device start the measurement

and connected to the atmosphere, while the devices for fixing the start and end of measurements are connected with an electronic stopwatch.

The disadvantage of this analyzer is the presence of a mercury differential pressure gauge as a differential meter, and it is known that mercury is a harmful substance, it is necessary to use special facilities to work with it, to train maintenance personnel. In addition, the design of the gas compression chamber made in the form of a bellows box slows down the heat transfer of the gas compressed in it and, as a result, reduces the measurement accuracy.

The objective of the utility model is to improve gas density analyzers based on the outflow of gas through the diaphragm.

EFFECT: creation of a simple and accurate density analyzer for verification and calibration of automatic gas density analyzers.

The technical result is achieved in that a density analyzer containing a miniature turbulent constriction device connected through a tee to a chamber for compressing the analyzed gas and with a differential meter including a “plus” chamber made flow-through, equipped with a device for fixing the end of measurements and connected through the inlet fitting to the line of the analyzed gas, and through the outlet fitting - with a tee and a "minus" chamber equipped with a device for fixing the beginning of measurements and connected to the atmosphere, while the device is fixed tion start and end measurements associated with electronic stop-watch, according to the utility model, further comprises pnevmotumbler connected to the outlet fitting miniature turbulent primary device and a syringe, the input channel of which is connected with the outlet chamber to compress the gas channel formed in the form of a spiral of a thin-walled tube. In this case, the diaphragm is divided into “plus” and “minus” chambers with a metal membrane, and the devices for starting and ending measurements are made in the form of needles, the tips of which

facing the two surfaces of the membrane with the possibility of the formation of two controlled by the pressure difference of the electrical contacts. In addition, the syringe body is equipped with a fitting, the location of which is due to the possibility of the formation of a flow chamber from the syringe with the piston extended as much as possible.

The proposed design of the analyzer provides greater accuracy in measuring density due to the design of a chamber for compressing gas in the form of a spiral from a thin-walled tube, which ensures rapid heat transfer of gas after it is compressed and heated with the environment, and also eliminates the need for installing the analyzer in special rooms and training staff for working with mercury, as The analyzer uses a membrane differential meter.

Compared with the prototype of the claimed design has a distinctive feature in the combination of elements and their relative position.

Figure 1 shows a diagram of a gas density analyzer.

The gas density analyzer contains a miniature turbulent constriction device 1 connected through a tee 2 with a chamber for compression of the analyzed gas 3 and with a differential meter 4. The differential meter 4 includes a positive camera 5 made flow-through, equipped with a device for fixing the end of measurements 6 and connected through an inlet fitting 7 with the line of the analyzed gas 8, and through the outlet nozzle 9 - with a tee 2 and a "minus" chamber 10, equipped with a device for fixing the beginning of measurements 11 and connected through the nozzle 12 to the atmosphere. Fixation devices for the beginning 11 and the end of measurements 6 are connected with an electronic stopwatch 13. The analyzer further comprises a pneumatic tumbler 14 connected to the outlet fitting 15 of the miniature turbulent constricting device 1 and a syringe 16, the input channel 17 of which is connected to the output channel 18 of the gas compression chamber 3 made in the form of a spiral from a thin-walled tube. The differential meter is divided into a “positive” 5 and

The “minus” 10 of the chamber is made of a metal membrane 19, and the devices of the beginning 11 and the end of 6 measurements are made in the form of needles, tips 20, 21 of which are turned towards two surfaces of the membrane 20 with the possibility of forming two pressure-controlled electrical contacts. The housing 22 of the syringe 16 is equipped with a nozzle 23, the location of which is due to the possibility of the formation of a flow chamber from the syringe 16 with the piston 24 extended as much as possible. The line of the analyzed gas 8 connected to the positive chamber 5 of the differential meter 4 through the nozzle 7 contains a valve 25.

The operation of the device is as follows.

Before starting the series of experiments, the devices for fixing the start of 11 and the end of 6 measurements are adjusted so that, at a small excess pressure P ₁ inside the chamber for compression of the analyzed gas 3, and therefore in the “positive” chamber 5 of the differential meter 4, the metal membrane 19 closes the circuit through contact 21 and gave a signal to the stopwatch 13, if there is an excess pressure P ₂ in the chamber greater than P ₁ , the membrane should be closed to contact 20.

Before starting the measurement, open the pneumatic toggle switch 14 and valve 25, and the piston 24 of the syringe 16 is extended to the extreme position so that gas is opened from the internal cavity of the syringe into the outlet 23. A source of compressed dried air is brought to line 8.

Air enters through the nozzle 7 and flushes the “positive” chamber 5 of the differential meter 4, a miniature turbulent constriction device 1, a chamber for compression of the analyzed gas 3 and the inner cavity of the syringe 16.

In this case, the gas remaining from the previous analysis is removed from the above elements. Then, the toggle switch 14 and the valve 25 are sequentially closed, and the outlet fitting 23 is closed by the piston 24 of the syringe 16 and an overpressure is created in the chamber. In this case, the membrane 19 moves and closes the contact 20 of the start of measurement 11. For some time, the air inside the chamber, heated as a result of compression, cools to ambient temperature

Wednesday. Then the toggle switch 14 is opened, and air flows into the atmosphere through a miniature turbulent constricting device 1 due to excess pressure in the inner cavity of the chamber. The parameters are selected so that the membrane does not immediately depart from contact 20, but closes it for some time under the action of pressure in the "positive" chamber 5 of the diaphragm 4. When the pressure inside the chamber becomes lower than the pressure P ₂ , the metal diaphragm 19 of the diaphragm moves away from the needle contact 20 the device starts measuring 11, the countdown begins. When the pressure becomes equal to P ₁ , the membrane closes the contact 21 of the device end measurement 6, the countdown stops. The time during which the pressure in the chamber has dropped from P ₂ to P ₁ is considered the time of expiration of the reference gas t _e .

Then, the source of the analyzed gas is connected to line 8, and all the operations described above are repeated. As a result of these two measurements, the time of expiration of the air t _e and the analyzed gas t _i through a miniature turbulent constriction device, calculate the density of the analyzed gas under normal conditions ρ _Ni , according to the following formula:

where ρ _ne is the air density under normal conditions.

The advantages of this technical solution are:

- the use of a membrane differential pressure gauge instead of a mercury one, eliminating the need to place the analyzer in a special room and staff training;

- reduction of the relative density measurement error due to the use of a chamber for gas compression in the form of a thin-walled tube having low thermal inertia;

- simplicity and expressness of density measurement.

The device can be implemented on the basis of a standard electronic time interval meter, membrane electro-contact pressure gauge, toggle switches, syringes and auxiliary devices.

The gas density analyzer can be used for rapid and accurate measurements of gas density in scientific and factory laboratories.

It can be widely used in the calibration and calibration of in-line automatic gas density analyzers as a standard means of measurement.

Claims (1)

A gas density analyzer containing a miniature turbulent constriction device connected through a tee to a chamber for compression of the analyzed gas and with a differential meter including a positive chamber made flow-through, equipped with a device for fixing the end of measurements and connected through the inlet fitting to the line of the analyzed gas, and through the outlet fitting - with a tee and a “minus” camera equipped with a device for fixing the beginning of measurements and connected to the atmosphere, while devices for fixing the beginning and end of measurements with They are equipped with an electronic stopwatch, characterized in that it further comprises a pneumatic toggle switch connected to the outlet fitting of the miniature turbulent constriction device and a syringe, the inlet channel of which is connected to the outlet channel of the gas compression chamber made in the form of a spiral from a thin-walled tube, while the differential meter is divided into The “plus” and “minus” chambers are made of a metal membrane, and the devices for starting and ending measurements are made in the form of needles, the tips of which are turned towards two membrane surfaces with possible the formation of two electric contacts controlled by the pressure difference, in addition, the body of the syringe is equipped with a fitting, the location of which is due to the possibility of the formation of a flow chamber from the syringe with the piston extended as much as possible.