RU2158421C2 - Device for gas sampling - Google Patents

Abstract

FIELD: monitoring of content of mechanical hard-dispersive particles in compressed gases. SUBSTANCE: device for gas sampling has probe coming in the form of contraction, sample-tapping tube connected to probe, conical chamber, sample intake branch pipe and sample analyzer. Conicity angle α of contraction is chosen within limits 5 deg<γ>25C. Sample intake branch pipe is manufactured in the form of hollow cylinder with inlet contraction having conicity angle γ chosen within limits 5 deg<γ<40C. Sample intake branch pipe carries handle mounted in its lower part and velocity indicator. Middle part of sample intake branch pipe has outer thread. Bushing with inner thread interacting with outer thread of sample intake branch pipe is installed in central part of lower base of conical chamber. Vertical symmetry axis of conical chamber , sample intake branch pipe, bushing and handle is located on one straight line. Plate having scale of flow velocity marked over its height is positioned vertically on peripheral part of lower base of conical chamber. EFFECT: increased reliability of gas sampling by way of provision of isokinetics of sampling, improved impressiveness of sample. 3 dwg

Description

 The invention relates to techniques for sampling gases and can be used to control the content of mechanical solid particles (impurities) in compressed gases (in air, nitrogen, helium, hydrogen, argon, neon, xenon, oxygen, etc.) used in space rocket engineering, aviation, engineering and in other sectors of the economy.

Known devices for gas sampling, implemented according to the method of Patent RU N 180411, MKI ⁶ G 01 N 1/22, 1963, containing a probe installed in the main pipeline, a sampling tube and an analysis device, for example, an analytical filter.

 The advantages of these devices are simple design, simplicity and speed of gas sampling.

Their main disadvantages include the following:
- the flow rates of the dispersed medium are not ensured in the sampling tube and in the main pipeline, as a result of which anisokinetic sampling of the gas instead of isokinetic takes place, which does not comply with the US Federal Standard. Cleanliness classes in airborne particles in finishing rooms and finishing areas. FED-STD-209E and GOST P 50766-95. The rooms are clean. Classification. Certification methods, Gosstandart of the Russian Federation, Moscow, 1995, therefore, these devices do not meet the criterion of isokinetic sampling;
- in case of isokinetic violation, the concentration of the selected particles will not be equal to the concentration of the dispersed medium in the main pipeline, therefore, the analyzed gas sample will not be representative, therefore, these devices do not meet the criterion of representativeness of the sample;
- at low speeds of the analyzed gas, impurities are deposited in the sampling tube, which significantly reduces the representativeness of the analysis.

 It follows from the foregoing that the devices in question do not provide the necessary reliability of operation and, therefore, do not meet the reliability criterion.

 A known method and device for sampling gases according to GOST 3022-TO, Gosstandart of the USSR, Moscow, 1970, containing a probe, a sampling tube, control valves, a sample analyzer and a bypass line.

The disadvantages of this device include:
- the inability to ensure isokinetic sampling of the gas due to the violation of the equality of the average speeds of the dispersed medium in the analysis and bypass lines;
- the complexity of the operational adjustment of costs by maneuvering control valves (by opening, closing).

 In addition to complicating operating conditions, this circumstance does not provide the necessary reliability of the device.

 Thus, the device in question does not meet the criteria of reliability, isokinetics, and hence the representativeness of gas sampling.

 A device for monitoring the content of mechanical impurities in compressed gases KBOM (leaflet, 1998), containing a housing, an isokinetic sampling chamber, a viewing device, rotameters, an inlet position control mechanism, valves, a throttle and an analytical filter chamber is known.

 The control mechanism uses a gear drive in which one gear is mounted on the lead screw and the other on the shaft, which ends with a handle located on the side of the device.

 The disadvantage of this device is the design complexity.

 In addition, large particles are deposited on the walls of the sampling tube, and submicron particles slip through the filter, which reduces reliability.

 The closest in technical essence and the achieved effect is a device for sampling gases according to EP 0219188 A1, class. G 01 N 1/22, 04/22/08, containing a probe made in the form of a confuser, a sampling tube connected to the probe, a conical chamber, a sampling port and a sample analyzer. This device is selected as a prototype.

The main disadvantages of the prototype are the following:
- when the base of the conical chamber is closed, due to gravity, particles settle in the volume and on the inner surface of the base, since the volume near the base is a kind of settler (stagnant zone), where the flow rate is zero, which reduces the reliability of the analysis;
- lack of funds for accurate installation of the sampling port in the desired section of the conical chamber at various flow rates in the main pipeline, which creates certain difficulties and often leads to a violation of the isokinetic sampling;
- the conical chamber is installed horizontally, which contributes to the fastest deposition of particles under the action of gravitational forces; this dramatically reduces the reliability of gas sampling.

 The objective of the invention is to increase the reliability of gas sampling by ensuring the isokinetic sampling and thereby the representativeness of the analyzed samples.

The stated technical problem is solved in that in the known device for sampling gases containing a probe made in the form of a confuser, a sampling tube connected to it, a conical chamber, a sampling pipe and a sample analyzer, the taper angle α of the confuser is selected within 5 ^o <α < 25 ^o , and the sampling pipe is made in the form of a hollow cylinder with an inlet confuser with a taper angle γ, selected within 5 ^o <γ <40 ^o , having a handle mounted in its lower part, and a speed indicator, while in the middle part it is sampled of the pipe, an external thread is made, and in the central part of the lower base of the conical chamber there is a sleeve having an internal thread interacting with the external thread of the sampling pipe, the vertical axis of symmetry of the conical chamber, the sampling pipe, sleeve and handle are located on one straight line and on the peripheral part the bottom base of the conical chamber is mounted vertically mounted plate, plotted along its height scale of the flow rate.

 The invention is illustrated by drawings, where in FIG. 1 shows a device for sampling gases; in FIG. 2 is a view along arrow A in FIG. 1; in FIG. 3 is a graph of the installation height of the sampling port H in the conical chamber versus the average flow rate W in the main pipeline.

 This graph is given as an example, showing the location of the sampling port in a conical chamber at different flow rates in the main pipeline. In each case there will be a similar schedule.

A gas sampling device comprises a probe 1, axisymmetrically mounted in the main pipe 2, a sampling tube 3 connected at one end to the probe and the other to a conical chamber 4, a sampling pipe 5, coaxially located in the conical chamber 4 and connected by a tube to the analyzer sample 6. The probe 1 is made in the form of a confuser with a taper angle α in the range 5 ^o <α <25 ^o . The inlet of the probe 1 is facing the gas flow in the pipeline 2.

The sampling pipe 5 is made with an inlet confuser with a taper angle γ selected within 5 ^o <γ <40 ^o in the form of a hollow cylinder equipped with a handle 8 and a speed indicator 9 installed in its lower part 7. In the middle part 10 of the sampling pipe 5, the outer thread 11, which interacts with the internal thread of the sleeve 12 located in the Central part of the lower base 13 of the conical chamber 4. The vertical axis 14 of the geometric symmetry of the conical chamber 4, sampling pipe 5, the sleeve 12 and the handle 8 is located married on one straight. In the peripheral part of the lower base 13 of the conical chamber 4, a vertical plate 15 is installed, the height of which is marked with a speed scale.

 During transportation and storage of the device, the lower base 13 of the conical chamber 4 is closed with a lid (in Fig. 1, the lid is conventionally not shown).

 The device operates as follows. The cover of the lower base 13 of the conical chamber 4 is opened. In this case, the two-phase flow (gas flow with solid particles) entering the inlet section of the probe 1 has the same speed and direction as the flow in the main pipeline 2, i.e., the conditions for sampling isokinetics are ensured , and consequently, the representativeness of the analyzed sample.

 Then, knowing the average flow rate in the main pipeline in the section where the inlet section of the probe is located, according to the schedule, for example, of FIG. 3, find the required installation height H of the sampling pipe in the conical chamber (Fig. 1).

 By rotating the handle 8, precisely set the arrow of the speed indicator 9 opposite the value of the flow rate in the main pipeline, shown on the scale of the plate 15. In this case, the required installation height H of the sampling inlet in the conical chamber is automatically achieved with full observance of the conditions for isokinetic sampling (i.e., with the same direction free flow and the equality of the average flow rates at the cut of the sampling pipe and at the same level in the conical chamber). After that, the concentration of solid particles in the analyzed gas is measured.

 When testing the proposed device, a high-precision aerosol particle counter PK.GTA-03-002V developed by the Vyborg Instrument-Making Plant was used as a sample analyzer.

To ensure continuity of the flow from the walls at the entrance, to reduce the input resistance and to maintain uniform distribution of the dispersed phase, the probe 1, made in the form of a confuser, has a taper angle α in the range of 5 ^o <α <25 ^o , which is confirmed by the test results of a real sampling device 8G332P. SB00 -460.

An analysis of the results of comparative tests of gas sampling devices with the proposed probe design and a cylindrical probe showed that at taper angles of 5 ^o <α <25 ^o the input resistance decreases, the flow is uniform, uninterrupted, and the difference in the concentration of particles in the sample from the concentration of particles in the test gas in the main pipeline is practically not observed.

 Along with this, the sampling conditions are improved especially at low flow velocities in the main pipeline (up to 15 m / s), not to mention large flow velocities reaching 30 m / s and more.

The implementation of the sampling pipe 5 with the upper inlet confuser part with a taper angle γ within 5 ^o <γ <40 ^o , found experimentally, excludes flow disturbance from the subsequent parts and their mutual influence on the entry conditions. The result is a smooth, uniform flow inlet into the sampling pipe and the uniform distribution of the dispersed phase in the stream is maintained, which generally increases the reliability of sampling in compliance with all isokinetic conditions.

 In the middle part 10 of the sampling pipe 5, an external thread 11 is made, screwed into the internal thread of the sleeve 12 located in the central part of the lower base 13 of the conical chamber.

 Such a constructive implementation, as the analysis shows, increases the performance, reliability, rigidity, stability and heat resistance of the sampling pipe when sampling hot and cold gases. The sleeve 12 is a guiding and centering element, while increasing the stability of the sampling pipe. Thanks to the sleeve 12, the rotational movement of the handle is converted into a reciprocating movement of the sampling pipe vertically up and down.

 The fact that the vertical axis of symmetry of the conical chamber, sampling pipe, sleeve and handle are located on one straight line, ensures their coaxiality, rigidity, stability and vibration resistance, without which the normal operation of the device is inconceivable.

 The supply of the sampling pipe with a handle and a speed indicator installed in its lower part allows, firstly, to accurately and quickly set the input section of the sampling pipe in the required section of the conical chamber, under which the conditions for sampling isokinetic are ensured, which cannot be achieved in the prototype and in analogues - secondly, by rotating the handle in one direction or another, it is easy to raise or lower the sampling pipe, which facilitates and accelerates the sampling process, thirdly, using the handle, the decree Telem speed and speed scale can be quickly and accurately prepare the device for operation under varying operating conditions of the main pipeline.

 On the plate 15, the speed scale can be performed practically at any division cost, for example, up to 1 m / s (Fig. 2), but the lower the division price, the more accurately the sampling port is installed in the conical chamber, and therefore, the more accurate the analysis result , which increases the reliability of the device.

To ensure operational efficiency, continuity of the gas flow and uniform distribution of the dispersed phase in the expanding gas stream, the conical chamber 4 is mounted vertically and made with a small taper angle β within 5 ^o <β <15 ^o , which increases the reliability of sampling in gravity [Deutch M E. "Technical gas dynamics", Moscow, SEI, 1961.].

 The manufacture of a gas sampling device is not particularly difficult and can be carried out under normal production conditions.

 Thus, the combination of features set forth in the claims, their indissoluble unity and purposefulness allow to obtain a significant positive effect, namely: to increase the reliability of gas sampling by ensuring isokinetic sampling and thereby representativeness of the analyzed sample.

 The invention was used in full when creating a device for sampling air in order to control its purity in the 8G332P system, designed for thermostating of space objects of the Icarus type on complexes 17P32-5 and 17P32-6.

Claims (1)

A device for sampling gases containing a probe made in the form of a confuser, a sampling tube connected to the probe, a conical chamber, a sampling port and a sample analyzer, characterized in that the taper angle α of the confuser is selected within 5 ^o <α <25 ^o , and the sampling port nozzles is formed as a hollow cylinder with inlets with a cone angle γ, selected in the range 5 ^o <γ <40 ^o, the handle having mounted in its lower part, and rate indicator, while in the middle of the sample probe outer tube made rez a, and in the central part of the lower base of the conical chamber a sleeve is installed that has an internal thread that interacts with the external thread of the sampling pipe, and the vertical axis of symmetry of the conical chamber, sampling pipe, sleeve and handle are located vertically on one straight line and on the peripheral part of the lower base of the conical camera a plate is mounted with a flow velocity scale plotted along its height.

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