RU2145083C1 - Gear for preparation of gas-vapor calibration mixture - Google Patents

Abstract

FIELD: analytical instrumentation, calibration and testing of gas analyzers. SUBSTANCE: gear includes case, vessel to saturate gas with vapors of substance installed in case, gas line to supply gas into vessel, gas line to release gas-vapor mixture from vessel, fixture to dilute gas-vapor mixture with additional flow of gas, gas line to supply additional flow of gas into fixture for dilution. Gas line to supply additional flow of gas into fixture for dilution is positioned separately from gas line that supplies gas into vessel for saturation. Vessel for saturation is manufactured in the form of cylindrical beaker installed inside case on mobile platform fitted with mechanism of its reciprocal motion in vertical direction. Cover for vessel provided with sealing ring that snugly contacts edges of vessel in uppermost position of platform is mounted immobile in upper part of case. Side wall of case has window fro removal of vessel out of case. EFFECT: expanded functional capabilities of gear for preparation of gas-vapor calibration mixtures. 4 cl, 1 dwg

Description

 The invention relates to the field of analytical instrumentation and may find application in the calibration of gas analyzers.

 A device is known for preparing a gas-vapor calibration mixture of substances, containing a saturation vessel filled with fluorinated carbon particles, between the layers of which the starting substance is placed, a gas line for supplying gas to the vessel, a gas line for withdrawing the gas-vapor mixture from the vessel, a device for heating the vessel, and a flow inducer gas (see part of ЕВП 0500938 A1, G 01 T 30/04, 1992).

 A disadvantage of the known device is its limited functionality. This is due to the fact that the known device allows you to change the concentration of the starting material in the gas in very narrow limits, since the change in concentration is provided only by changing the temperature of the vessel for saturation. In addition, the range of starting materials suitable for the preparation of a gas-vapor mixture is also very limited.

 The closest in technical essence to the proposed device is a device for preparing a gas-vapor calibration mixture of substances, comprising a housing, a vessel for saturating gas with vapor of a substance installed in the housing, a gas line for supplying gas to the vessel for saturation, in which an absorber of interfering mechanical impurities and impurities is installed substances, a gas line for withdrawing the gas-vapor mixture from the vessel, a device for diluting the gas-vapor mixture, installed in the gas line for withdrawing the gas-vapor mixture from saturation vessels, a gas line for supplying a dilution gas stream to a dilution device in which constant pneumatic resistance is installed, a tee connecting a gas line for supplying gas to a saturation vessel and a gas line for supplying a dilution gas and determining the degree of dilution of the gas-vapor mixture in the device for dilution, and a stimulator of gas flow (see generators of calibration concentrations of vapor in the air company Cavkit Ltd (England), 1997).

 A disadvantage of the known device adopted for the prototype is its limited capabilities. This is due to the fact that in the known device, the gas line for supplying gas to the vessel and the gas line for supplying dilution gas are combined into a tee, which sets a rigid flow ratio in the dilution device and determines the concentration of steam in the gas at the device outlet. The transition to a new concentration at a given temperature can only be carried out stepwise by replacing the tee with pneumatic resistance, which requires stopping the device, disconnecting the gas lines from the tee, replacing the tee, tightly connecting the gas lines to it, etc. All this significantly complicates the operation of the device. The limited functionality of the device is also due to the fact that as the starting materials for the preparation of calibration gas-vapor mixtures in the device, a very limited range of substances can be used for which the exact values of the vapor pressure at different operating temperatures of the device are known, since the calculation of the concentration of steam in the gas on the output of the device is based on these data and taking into account the division ratio of the gas flow in the tee.

 A disadvantage of the known device is the lack of accuracy in setting the concentration of the calibration gas-vapor mixture. The reason for this is the lack of accurate temperature dependences of saturated vapor pressure. The dependence course in the interval between known pressure values is unknown and is set using interpolation.

 The objective of the invention was to expand the functionality of the device for the preparation of calibration gas-vapor mixtures and increase the accuracy of preparation of gas-vapor mixtures.

 This problem is solved by the fact that a device for preparing a gas-vapor calibration mixture is proposed, comprising a housing, a vessel for saturating gas with vapor of a substance installed in the housing, a gas line for supplying gas to a vessel for saturation, in which an absorber of interfering mechanical impurities and impurities of substances is installed, gas a line for withdrawing the gas-vapor mixture from the vessel, a device for diluting the gas-vapor mixture, installed in the gas line for withdrawing the gas-vapor mixture from the vessel for saturation, a gas line for two dilution gas flows into the dilution device and a gas flow inducer, in which according to the invention the gas line for supplying the dilution gas stream to the gas-vapor mixture dilution device is made separately from the gas line for supplying gas to the saturation vessel, and an additional interfering absorber is introduced into the device mechanical impurities and impurities of substances and a gas flow regulator installed in the gas line for supplying a dilution gas stream to the dilution device.

 Another difference of the proposed device is that the vessel for saturation of the gas with vapor of the substance is made in the form of an easily removable element with the possibility of extracting it from the housing.

 In a preferred embodiment of the device, the saturation vessel is made in the form of a cylindrical cup mounted inside the housing on a movable platform equipped with a mechanism for its reciprocating movement in the vertical direction, with a vessel cover fixedly provided in the upper part of the housing provided with a ring of elastic inert material with which the edges of the vessel are in close contact at the extreme upper position of the platform, and in the side wall of the housing there is a window for removing the vessel and from the body.

 Another difference of the proposed device is that the lid of the vessel is equipped with nozzles connected to gas lines for supplying gas and outputting a gas-vapor mixture.

 Among the differences, it should be noted that the platform on which the vessel for saturation is installed is equipped with a thermoelectric converter to set the vessel to maintain the set temperature.

 Due to the above-mentioned features of the proposed device, the device’s functionality is expanded, since the device allows you to smoothly change the concentration of steam in the gas at the device’s outlet over a wide range and use a wide range of substances to prepare the gas-vapor mixture. In this case, the calculation of the concentration of steam in the gas is carried out on the basis of periodic weighing of the vessel removed from the housing, which increases the accuracy of determining the concentration.

 The invention is illustrated in the drawing, which shows the proposed device in vertical section and a diagram of its gas lines.

 The device comprises a housing 1, in which a vessel 2 is placed to saturate the gas with vapor of a substance. The vessel 2 is made in the form of a cylindrical glass of inert material (stainless steel), partially filled with liquid substance 3, mounted on a movable platform 4, equipped with a mechanism 5 for its reciprocating movement in the vertical direction. In the upper part of the housing 1, the cover 6 for the vessel 2 is fixedly mounted, provided with a ring 7 of elastic inert material, for example silicone rubber, which serves to tightly seal the end surface of the vessel 2 at the extreme upper position of the platform 4. The cover 6 is also equipped with nozzles 8 and 9 for supply and gas outlet from the vessel 2. The pipe 8 is connected to a gas line 10 for supplying air, in which an absorber 11 is installed for trapping interfering mechanical impurities and impurities from the air. The absorber 11 is a tube filled with sorbent particles to absorb moisture (silica gel) and organic impurities (activated carbon). At the inlet of the absorber tube 11 there is a grid for trapping mechanical particles, such as dust and smoke. The pipe 9 is connected to the gas line 12 for withdrawing the gas-vapor mixture from the vessel 2, which is connected to one of the inputs of the device 13 for diluting the gas-vapor mixture, the other inlet of which is connected to the gas line 14 for supplying dilution air. As a device 13 for dilution can be used tee. In the gas line 14 for supplying dilution gas, an absorber 15 of interfering mechanical impurities and impurities of substances and a gas flow regulator 16 are sequentially installed. The absorber 15 is made similar to the absorber 11. The gas line 14 for supplying a dilution gas stream to the device 13 for diluting the gas-vapor mixture is made separately from the gas line 10 for supplying gas to the vessel 2 for saturation so that the gas inlet 17 of the gas line 14 is not connected to the gas inlet 18 of the gas line 10. The output of the device 13 for diluting the gas-vapor mixture is connected to a graduated gas analyzer 19, the output of which is connected to the inducer 20 of the gas flow. A diaphragm type pump, which is usually used in a graduated gas analyzer 19, can be used as a gas flow inducer 20.

 In the side wall of the housing 1, a window 21 is made for removing the vessel 2 for the purpose of periodic weighing. The platform 4, on which the vessel 2 for saturation is installed, is equipped with a thermoelectric converter 22 mounted on the lower surface of the platform 4 and designed to maintain the desired temperature of the vessel 2. The mechanism 5 for moving the platform 4 is equipped with handles 23 to give it a rotational movement, which is converted back - translational movement of the platform 4. On the upper horizontal surface of the platform 4 there is a circular recess in the shape of the bottom of the vessel 2, designed to center the vessel 2 relative to the axis of the cylindrical body 1 and the sealing ring 7 in the cover 6.

 The proposed device operates as follows. The vessel 2 is partially filled with a liquid source substance 3, for example, hexane, and weighing is carried out on an analytical balance (not shown in the drawing) in order to determine the initial amount of the initial liquid substance in the vessel 2. Then, the vessel 2 is installed on the platform 4 through the window 21 in the housing 1 round recess and by rotation of the mechanism 5 with the help of the handles 23 lift the platform 4 to the extreme upper position, in which the end face of the surface of the vessel 2 is in close contact with the sealing ring 7, thereby sealing the internal volume of the vessel 2. Then, using a thermostat (not shown) and a thermoelectric converter 22, a predetermined operating temperature is established in the vessel 2 and a gas flow inducer 20 and a graduated gas analyzer 19 are turned on. The gas flow inducer 20 creates a vacuum at the outlet of the gas analyzer 19, begins pumping gas streams entering the device through the gas inlets 17 and 18 of the gas lines 14 and 10, respectively, from the surrounding air. The gas stream flowing through the gas line 10 is cleaned of particles of mechanical impurities, as well as moisture and organic substances contained in the air, in the absorber 11 and through the pipe 8 enters the internal volume of the vessel 2, where it is saturated with vapors of the starting material and through the pipe 9 through the gas line 12 for outputting the gas-vapor mixture enters the device 13 for dilution. At the second input of the dilution device 13, a diluent air stream is sucked in through the gas line 14 and is sucked in through the gas inlet 17, which is mixed with the gas-vapor mixture flowing through the gas line 12, and the diluted gas-vapor mixture flows into the graduated gas analyzer 19. The gas analyzer 19 is in the process work generates an electrical signal proportional to the concentration of vapor of the substance in the gas at the output of the device 13 for dilution. The vapor concentration of the substance in the gas at the outlet of the dilution device 13 is calculated based on data on the volumetric gas flow rates in the gas lines 10 and 14 and data on the change in the amount of substance in the vessel 2 over a certain period of time. Measurement of gas flow in gas lines 10 and 14 is carried out by connecting to them or connecting to their input gas flow meters, for example a rotameter or foam gas flow meter (not shown). The measurement of the amount of substance transferred in the form of steam from the vessel 2 into the gas stream passing through the vessel 2 and removed from it through the gas line 12 is carried out by periodically removing the vessel 2 from the housing 1 and weighing it on an analytical balance (not shown). Removing the vessel 2 from the housing 1 is carried out by lowering the platform 4 to a level at which the vessel 2 is installed opposite the window 21, and removing the vessel 2 through the window 21.

 The transition to a new value of the concentration of steam in the diluted stream of the gas-vapor mixture entering the gas analyzer 19 is carried out by continuously adjusting the resistance to the gas stream in the gas line 14 using the gas flow controller 16. It can also be carried out by changing the temperature of the vessel 2 using a thermoelectric converter 22.

Claims (5)

 1. A device for preparing a gas-vapor mixture, comprising a housing, a vessel for saturating gas with vapor of a substance, installed in the housing, a gas line for supplying gas to the vessel for saturation, in which an absorber of interfering mechanical impurities and impurities of substances is installed, a gas line for withdrawing the gas-vapor mixture from vessels, a device for diluting a gas-vapor mixture, installed in a gas line for withdrawing a gas-vapor mixture from a vessel for saturation, a gas line for supplying a stream of dilution gas to the decomposition device phenomena and stimulator of gas flow, characterized in that the gas line for supplying a dilution gas stream to the device for diluting the gas-vapor mixture is made separately from the gas line for supplying gas to the saturation vessel, and an additional absorber of interfering mechanical and substance impurities and a regulator are introduced into the device gas flow rates installed in the gas line for supplying a dilution gas stream to the dilution device.  2. The device according to claim 1, characterized in that the vessel for saturating the gas with vapor of the substance is made in the form of an easily removable element with the possibility of removing it from the housing without disconnecting the gas lines.  3. The device according to claim 2, characterized in that the vessel for saturation is made in the form of a cylindrical cup mounted inside the housing on a movable platform equipped with a mechanism for its reciprocating movement in the vertical direction, and a lid for the vessel is fixedly mounted in the upper part of the housing equipped with a ring of elastic inert material with which the edges of the vessel are firmly in contact with the extreme upper position of the platform, and a window is made in the side wall of the housing for removing the vessel from the housing.  4. The device according to claim 3, characterized in that the lid for the vessel is equipped with nozzles connected to gas lines for supplying gas and outputting a gas-vapor mixture.  5. The device according to claim 3 or 4, characterized in that the platform on which the vessel for saturation is mounted is equipped with a thermoelectric converter to maintain a given temperature of the vessel.