RU2447407C1 - Capillary diffusion source of vapour microstream - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: capillary diffusion source of a vapour microstream has a sealed gas-impermeable cylindrical housing with a working fluid - liquid phase of the analysed substance. A capillary with inlet and outlet holes on its corresponding sections is tightly attached to one of the end parts of the housing. The source also has support legs for holding it in the working horizontal position and preventing it from tipping over. The support legs are attached directly to the housing, and the capillary is tightly attached to the end part of the housing by its outlet section and is fitted inside the housing in parallel and above its axis such that the inlet hole of the capillary lies at a comparable distance from the ends of the housing. The support legs are attached to the housing at the opposite side of the outlet hole of the capillary.

EFFECT: high volume of working fluid, reduced probability of the working fluid falling into the capillary, preventing condensation of the analysed substance in the capillary.

2 cl, 4 dwg, 2 tbl

Description

The invention relates to physico-chemical methods for monitoring, analysis and metrological support of gas analytical equipment and can be used for dosing a microflow of a pair of volatile substances in the preparation of vapor-gas mixtures with a known content of the analyzed component.

Sources filled with the liquid or solid phase of the analyte at a constant temperature (certification) and saturated vapor pressure of the analyte create a constant pressure drop at the inlet and outlet of the capillary, which creates a constant flow of the analyte.

The stability of the microflow sources performance, in addition to the temperature and pressure of the gas carrier, is mainly influenced by the cleanliness of the inner surface of the capillary tube, which can be affected by changes in the ambient temperature, during installation in the thermostat, or when it is removed from it due to the appearance of condensate in the capillary or getting into it liquids.

Known diffusion source of microflow of steam (US 2009255351 (A1), 2009-10-15), which contains a horizontally oriented gas-tight cylindrical body in the form of a segment of a hollow pipe with sealing plugs at its ends. One of the plugs contains a number of capillaries and a partition that is transparent to steam. A solid working substance to be filled in the body - ammonium carbamate at a certain temperature releases ammonia, which creates a pressure drop at the inlet and outlet of the capillaries - a constant flowing out stream of the analyte.

A known source cannot be used to analyze liquid substances.

A diffusion source of steam microflow is also known, which is used in a diffusion micro-concentration doser (SU 1409868, G01F 13/00, 07/15/1988).

The dispenser contains a vertically oriented container with a dosing liquid, placed in a thermostat and connected through a diffusion tube in a tube with a mixer. The mixer inlet is connected to a diluent gas source, and the outlet to a mixture consumer. The inlet of the diffusion tube is located above the level of the dosed liquid in the tank, and the walls of the tank are provided with thermal insulation.

Diffusion dispenser microconcentrations works as follows.

Liquid is poured into an open container without a diffusion tube, the dispenser is closed with a stopper and placed in a thermostat. The mixer and diffusion tube are purged with diluent gas. After temperature control of the dispenser, a mixer with a diffusion tube is inserted instead of the stopper and the set value of the diluent gas flow is set. After 5-10 minutes, the resulting mixture will contain the calculated microconcentration of the dosed vapors, which is defined as the ratio of the diffusion stream to the diluent gas stream.

The diffusion flow is controlled by changing the temperature of the thermostat or by replacing the diffusion tube with another with a different internal diameter and length.

The known device has significant dimensions, necessitating the use of thermostats with large thermostatically controlled chambers and, accordingly, a long time for both preliminary preparation of the device for operation and, if necessary, a change in temperature of thermostating, which, in turn, requires excessive consumption of diluent gas .

Also known is a capillary diffusion source of a microflow of a vapor of an analyte (VICI Metronics 2991 Corvin Drive, Santa Clara, CA 95051 USA Phone: (408) 737-0550, Telex: 35-2129 - company prospectuses, permeable sources of "Danacal" Capillary diffusion tubs.) , which in terms of essential features is the closest analogue to the proposed source.

The known capillary source of steam microflow contains a sealed gas-tight cylindrical glass case with a working fluid - the liquid phase of the analyte and a capillary, tightly and with an eccentricity attached to the end of the case with its inlet section. The inlet section of the capillary is equipped with persistent legs, for fixing the source in a horizontal position and protecting it from tipping over.

The length (~ 75 mm) and the internal size of the capillary (from 0.5 to 5 mm) determine its diffusion resistance to the outgoing vapor stream of the analyte. To increase the volume of the liquid phase of the analyte, that is, its life, the capillary is connected to the housing with an eccentricity (+ "e"), relative to the axis of the housing.

A known source of microflow operates as follows.

After filling the body of the microflow source with the liquid phase of the analyte, the level of which should be lower than the inlet of the capillary, carefully, preventing liquid from entering the capillary, install the source in a horizontal position in the thermostatic chamber of the calibrator with a given temperature (from 40 to 350 ° C).

If liquid enters the capillary with a possible tilt of the source, it will take a long time to blow out the liquid phase of the analyte from it, which affects the stability of the generated diffusion vapor stream.

A stable flow of diluent gas (usually nitrogen - N ₂ ) is supplied through the inlet of the thermostat with a given flow rate. The output to the operating mode is determined by the stable outflow through the outlet pipe of the calibration gas mixture of the analyte at the certification temperature.

The sequential arrangement of the capillary relative to the housing determines the total length of the microflow source (up to 15.2 cm).

Working with a well-known capillary source of microflow requires qualified service and experience, especially necessary when filling the source with working fluid and when installing it in a thermostat. To reduce the possibility of liquid entering the capillary when the source is tilted, its body is usually filled with a smaller volume of liquid.

Increased requirements are also imposed on the thermostat in terms of the absence of a temperature gradient in its working space, since due to the spatial separation of the body and capillary, the vapor of the substance can condense in the capillary even with a slight difference in temperature of the vapor of the substance in the housing and in the capillary itself. The condensate in the capillary affects the stability of the composition of the diffusion vapor stream of the analyte in the prepared vapor-gas mixtures.

The reasons that impede the achievement of the technical result indicated below when using the known device include a short life of the source and the complexity of its operation.

The task to which the invention is directed is to increase the life of the source and simplify operating conditions.

The technical result obtained by carrying out the invention consists in increasing the volume of the working fluid while maintaining the dimensions of the source, reducing the possibility of the working fluid getting into the capillary during operation and eliminating the occurrence of condensate of the analyte in the capillary.

The specified technical result during the implementation of the invention is achieved by the fact that in the inventive capillary diffusion source of steam microflow, containing a sealed gas-tight cylindrical body with a working fluid - the liquid phase of the analyte, hermetically attached to one of the end parts of the body a capillary with inlet and outlet openings in its corresponding sections and support legs for fixing the source in a working horizontal position and protecting it from tipping over, in contrast to source, support legs are attached directly to the housing, and the capillary is hermetically attached to the end of the housing with its outlet section and is installed inside the housing parallel to and above its axis so that the inlet of the capillary is commensurate from the ends of the housing.

The specified technical result in the implementation of the invention is also achieved by the fact that the support legs are attached to the housing on the opposite side from the outlet of the capillary.

Figure 1 shows a conditional image of the inventive source of microflow steam in the working position; figure 2 is the same, view along section AA; figure 3 is a graphical illustration of calculating the area of a circle segment from a known source VICI Metronics; figure 4 is the same for the claimed source.

The inventive capillary diffusion source of steam microflow (Fig. 1) contains a sealed gas-tight cylindrical housing 1 with a working fluid 2 in its lower part and a capillary 3 sealed to the housing 1. The capillary 3 is hermetically attached to the end part 4 _{1 of the} housing 1 with its outlet section 5 s an outlet 6 and is installed parallel and above the axis of the housing 1 inside its upper part 7. The length of the capillary 3 is selected so that its inlet 8 is located at a comparable distance from the ends 4 ₁ and 4 _{2 of the} housing 1. The support legs 9 ₁ and 9 ₂ (figure 2), fixing the source in the working horizontal position and protecting it from tipping over, are attached directly to the housing 1, preferably on the opposite side from the outlet 6 of the capillary 3.

The microflow source operates as follows.

The case 1 of the microflow source is filled with the liquid phase 2 of the analyte (for example, a volume equal to half the volume of the internal space of the case), the level of which should be lower than the inlet 8 of the capillary 3. The case 1 is moved to a thermostatic chamber of the calibrator (not shown in Fig.). In the chamber, the housing 1 is positioned on the legs 9 ₁ and 9 ₂ and then the source housing 1 is installed in a horizontal operating position.

Upon reaching the temperature stabilization mode (certification temperature) of the source, a stable stream of diluent gas (usually nitrogen - N ₂ ) is supplied through the inlet pipe of the calibrator thermostat with a given flow rate. Under the action of the generated pressure of saturated vapors of the analyte in the housing 1 at the outlet of the capillary 3, a stable steam flow is established, which, mixed with the diluent gas washing the microflow source, forms a calibration gas mixture entering the outlet pipe. The output to the operating mode is determined by the stable outflow through the outlet pipe of the calibration gas mixture of the analyte at the certification temperature.

Since the length of the housing 1 at the claimed source, ceteris paribus, is greater than that of the known source, then, accordingly, a larger volume of the filled working fluid 2 provides a longer service life.

Since when moving the source, the working fluid 2 is located in the part of the housing 1 without the capillary 3 and does not come into contact with its inlet 8, and the positioning of the source in the thermostat chamber begins with the installation of the source on a pair of legs 9 ₁ and 9 ₂ and the further inclination of the housing 1 to its horizontal operating position, the ingress of liquid into the capillary 3 is excluded.

Both the well-known VICI Metronics - (1) and the claimed - (2) sources can be made, for example, from the following materials (GOST 27460-87 (ST SEV 743-86) Tubes, capillaries and sticks made of borosilicate glass 3.3. General specifications).

Table 1 An object Diameter mm Wall thickness mm Length L mm Outer Interior Housing (tube) twenty 16,4 1.8 75 (VICI Metronics) 150 (claimed) Capillary 6 0.5 2.75 75 6 1,0 2.5 6 2.0 2.0 Capillary (diffusion tube) 7 5,0 1,0

The calculation of the maximum volumes of liquid V ₁ and V ₂ (without taking into account the wettability phenomenon) with the possibility of visual control of its level height - at the known (1) source (VICI Metronics) - to the lower boundary of the capillary inlet, at the declared (2 *) source - up to the surface of the capillary (figure 3 and 4).

V = L · S _seg .

The calculation of the area of the segments of the circle S _SEG was carried out using the online calculator (http://www.fxyz.ru) according to the data: α ° (arc angle of the segment ≤180 °) and R (radius of the segment).

S _seg = πR ² -S _1,2 (α, R),

where L ₁ = 7.5 cm, L ₂ = 15 cm, R = 0.82 cm, πR ² = 2.1124 cm ² , α ° = 2 arccos (R-2r) / R

table 2 VICI Metronics source capillary diameter, claimed * cm (R-2r) / R (cos α / 2) Angle α ° of the arc segment S ₁ or S ₂ *, optional up to 360 ° Segment area, S ₁ or S ₂ * additional to a circle area of cm ² Segment area S _seg cm ² The volume of fluid V ₁ and V ₂ * cm ³ 0.05 0.9390 40.2314 0.4532 1.6592 12,4440 0.10 0.8780 57.1959 0.6182 1.4942 11,2065 0.20 0.7561 81.7578 0.8125 1,2999 9,7493 0.50 0.3902 134.0661 1,0282 1,0842 8.1315 0.6 * 0.2883 * 146.4876 * 1,0452 * 1,0672 * 16,0081 * 0.7 * 0.1463 * 163.1749 * 1.0548 * 1.0576 * 15,8642 *

The constructive implementation of the claimed capillary diffusion source of microflow of steam due to the location of the capillary inside the housing directly in the vapor of the substance allows you to:

- increase the life of the source by increasing the volume of the working fluid in the source while maintaining its overall dimensions;

- reduce the possibility of the ingress of working fluid into the capillary due to the confident positioning of the source in a horizontal working position;

- make the source in the form of a single monoblock and thereby, by ensuring equal temperatures of the capillary and the vapors inside the housing, eliminate the possibility of vapor condensation inside the capillary.

Thus, it is seen that the above information confirms the possibility of implementing the claimed invention, achieving the specified technical result and solving the problem.

Claims (2)

1. Capillary diffusion source of steam microflow, containing a sealed gas-tight cylindrical body with a working fluid - the liquid phase of the analyte, hermetically attached to one of the end parts of the body a capillary with inlet and outlet openings in its corresponding sections and support legs for fixing the source in a working horizontal position and preventing it from tipping over, characterized in that the support legs are attached directly to the housing, and the capillary is hermetically attached to the torus the central part of the housing with its outlet section and is installed inside the housing parallel to and above its axis in such a way that the inlet of the capillary is commensurate from the ends of the housing. 2. The source of steam microflow according to claim 1, characterized in that the support legs are attached to the housing on the opposite side from the outlet of the capillary.

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