RU2256898C1 - Arrangement for definition of availability of suspended particles including microorganisms in condensed gases - Google Patents

Abstract

FIELD: the invention refers to devices controlling condensed technological gases.

SUBSTANCE: demands are made from these devices to defy the availability of suspended particles - microorganisms. The invention may be used in pharmacology, biotechnology, food and cosmetic industries. The arrangement for definition of availability of suspended particles in condensed gases has a working chamber, provided with input and output. A facility for catching suspended particles is installed in its cavity. The arrangement has a facility for stabilization of gas consumption which is located after the mentioned working chamber along the movement of gas flow and which has a facility for regulation of pressure and a facility for regulation of the gas flow section. The facility for regulation of the gas flow section is installed after the facility for regulation of pressure along the gas flow. The facility for catching particles is fulfilled in the shape of a gas-proof filter which is installed in such a manner that the gas flow passes the cavity of the working chamber from its input to the output through the mentioned filter.

EFFECT: the invention is extremely accurate and allows to select reliable samples; simple in using.

13 cl, 1 dwg

Description

The invention relates to means for monitoring compressed technological gases, which have special requirements for the content of suspended particles: microorganisms, or mechanical microparticles, and can be used in the pharmacological, biotechnological, food, cosmetic industries for microbiological control of gases used in technological processes for the preparation of drugs, food, beverages, cosmetics, as well as in the electronics industry to control the content of mechanical their impurities in gases used in technological processes in the manufacture of microcircuits (etc.).

Health and life of people depend on the quality of food, drinks, cosmetics and medicines, therefore, serious attention is paid to their safety. To ensure safety, all components of the technological process for the preparation of these products are subject to strict control. For example, in order to ensure the safety of pharmacological and food products, microbiological monitoring of the air of industrial premises where these products are manufactured is carried out. A known device designed for such monitoring is an AirPort MD8 device developed by Sartorius (Germany). The apparatus comprises a working chamber equipped with an inlet and an outlet, at the entrance to which a gas-permeable gelatin filter is installed, and means for forcing air to pass through the working chamber so that the air flow passes through the gelatin filter. When the apparatus is operated, microorganisms present in the air are deposited on a gelatin filter. After stopping the apparatus, the gelatin filter is removed from the working chamber and placed in an appropriate nutrient medium, where, under certain incubation conditions, colonies of microorganisms grow on it against which air is tested. According to the number of colonies grown, the CFU / m ³ indicator is determined [AirPort MD8, Meta advertising brochure].

The quality of technological compressed gases (air, nitrogen, helium, hydrogen, argon, neon, xenon, oxygen, etc.) used in rocket and space technology, aviation, microelectronics, along with other parameters is determined by the content of undesirable mechanical solid particles in them, therefore enterprises constantly monitor such gases using special devices. For example, a device for sampling high-pressure compressed gases is known, including a probe, a sampling tube connected to it with a shut-off valve, a throttle, a conical chamber, a sampling port and a sample analyzer [RF patent No. 2152017, IPC G 01 N 1/22, publ. 06/27/2000]. The throttle is made in the form of a combined nozzle consisting of inlet cone, cylindrical and outlet diffuser parts connected in series. The conical chamber is made integral with the upper part passing into the diffuser part of the combined nozzle and the lower one open at the base. The disadvantage of this device is that it is suitable for determining the content of mechanical suspended particles, but unsuitable for determining the content of microorganisms in compressed gases. In addition, the device does not allow to determine the composition of the solid particles contained in the gas and their sizes, which is sometimes necessary.

To ensure the safety of medicines, food, drinks and cosmetics, strict quality control is carried out not only of the air in production facilities, of all ingredients included in the preparations and products, but also of substances involved in the technological process of their preparation. Compressed process gases are used in pharmacology for purging tanks and reactors, crushing, bubbling. mixing, and in the food industry - for purging tanks and reactors, cleaning, cooling and freezing products, in cosmetology - for purging tanks and reactors, cleaning, cooling and freezing cosmetics and their ingredients, so their quality is subject to strict control, in particular microbiological control for the presence, quantitative and qualitative composition of harmful and pathogenic microorganisms. Compressed process gases, as a rule, are supplied to the working areas via gas pipelines or cylinders.

A device for the determination of microorganisms in compressed gases and air M Air T, developed by Millipore (USA) specifically for monitoring the microbiological quality of compressed gases used in the preparation of drugs, food and beverages. It contains:

- a working chamber equipped with an inlet and an outlet through which the flow of the gas being tested passes;

- a perforated plate mounted in the cavity of the working chamber perpendicular to the gas flow for uniform distribution of the gas flow over the cross section of the working chamber;

- means for trapping microorganisms contained in the gas stream, made in the form of a gas-tight cartridge; with an agar nutrient medium mounted perpendicular to the gas stream, onto which microorganisms inertia precipitate when the gas stream passes through the working chamber;

- means for reducing the inlet pressure, which is installed before entering the working chamber along the gas flow [M Air T compressed Gas and Air Sampling Kit. User Guide - www.milipore.com].

This device for the greatest number of similarities with the proposed device features is its closest analogue and is taken as a prototype of the invention.

The prototype has the following disadvantages:

- the flow of the test gas before entering the working chamber passes through a means to reduce the inlet pressure, where, due to the pressure decrease, the specific humidity in the stream decreases and some microorganisms are dehydrated, as a result of which they die, therefore, the gas flow with a known lower CFU / m ³ relatively real;

- when the air stream passes through the perforated plate, part of the microorganisms may linger on the plate, which leads to an underestimation of the real value of CFU / m ³ ;

- when enveloping a distributed gas stream of a cartridge with an agar nutrient medium, part of the microorganisms is carried away by a gas stream from the working chamber, past the cartridge, which ultimately leads to an underestimation of the real indicator of CFU / m ³ ;

- to calculate CFU / m ³ when using the device, it is necessary to measure the volume of gas that has passed through the working chamber and the time during which this volume has passed through the working chamber, and time is measured using known means rather easily, and gas volume measurement is more complicated;

- the device is suitable only for monitoring compressed gases containing microorganisms, and is unsuitable for monitoring compressed gases containing solid mechanical particles.

The invention solves the problem of creating a universal device for determining the content of suspended particles in compressed gases, suitable for working with gases containing both microorganisms and solid mechanical particles, which allows to determine the qualitative composition of suspended particles and has high accuracy, especially when determining the content of microorganisms in compressed gases , while easy to use - not requiring measurements of the volume of gas passing through the working chamber.

The problem is solved by the fact that a device for determining the content of suspended particles (solid mechanical or microorganisms) in compressed gases, including

- a working chamber equipped with an inlet and an outlet, in the cavity of which there is installed a means for collecting suspended particles in such a way that the gas flow passes through the cavity of the said chamber from its inlet to the outlet through the said means, which is made in the form of a gas-permeable filter;

- means for stabilizing the flow of gas leaving the working chamber, which is located along the gas flow after the said working chamber, containing means for normalizing the gas pressure and means for normalizing the cross section of the gas flow located along the gas.

The gas pressure rationing means can be made in the form of a chamber equipped with an inlet and an outlet, at the inlet of which an inlet valve is installed, which regulates the gas flow depending on the pressure in the said chamber. The means for regulating the cross section of the gas stream can be made in the form of a membrane with a central hole, the size of which is adjustable, or a throttle with an adjustable size of the outlet, which allows you to force a certain size of the cross section of the gas stream. To increase the area of the gas-permeable filter under normal aerodynamic conditions in the cavity of the working chamber, it can be made in the form of a mating diffuser (on the inlet side) and confuser (on the outlet side), and a gas-permeable filter is installed in its cavity perpendicular to the gas flow in place their pairing.

To connect to a source of compressed gas, the inlet of the working chamber must be equipped with a means of connection with the named source, for example, a fitting or pipe.

To ensure sedimentation of suspended particles (microorganisms and mechanical impurities) on a gas-permeable filter, it can be made in the form of a plate of porous or mesh material, or a continuous material with perforation, and the pore or holes in it must be smaller than the size of the particles to be trapped.

To increase the accuracy of determining the gas flow, the means for stabilizing the gas flow can be equipped with a temperature sensor. It is advisable to install this sensor after the means for normalizing the gas pressure, before the means for regulating the cross section of the gas flow.

To reduce the noise of the gas passing through the throttle, the means for stabilizing the gas flow can also be equipped with a noise muffler.

If the filter material is not strong enough, for its safety and convenience when removing the filter from the chamber, it is advisable to provide it with a gas-permeable substrate.

The proposed device is schematically depicted in the drawing, where 1 is the working chamber, 2 is the input fitting of the working chamber, 3 is the input of the working chamber, 4 is the output of the working chamber, 5 is the diffuser of the working chamber, 6 is a gas-permeable filter, 7 is a gas-permeable substrate for a gas-permeable filter 8 - confuser of the working chamber, 9 - O-ring seal, 10 - fitting at the outlet of the working chamber, 11 - means for stabilizing the gas flow, 12 - inlet fitting of the means for regulating gas pressure, 13 - means for regulating the gas pressure, 14 - chamber for means for stabilizing the gas flow , fifteen - temperature sensor, 16 — means for regulating the cross section of the gas flow, 17 — silencer, 18 — connecting pipe, 19 — compressed gas pipeline, 20 — sampler.

A device for determining the content of suspended particles in compressed gases works as follows.

By means of a fitting and flexible hoses 18, the inlet 3 of the working chamber 1 is connected to a source of compressed gas, for example, connected to a main line through which compressed gas is supplied (pipe 19), or to a cylinder with compressed gas. The sampler 20 is moved to the “open” position and the gas flow due to its own pressure enters through the inlet 3 into the diffuser 5 of the working chamber, where, expanding, it loses part of its speed and passes through a gas-permeable filter 6 provided with a gas-permeable substrate 7. In this case, the gas-permeable filter suspended particles contained in the gas stream are deposited: solid mechanical, or microorganisms. Next, the gas stream enters the confuser 8 of the working chamber, compressing in the direction of movement, and through the outlet of the working chamber 4, fitting 10, flexible hoses 18 enters the means for stabilizing the gas flow 11. The means for stabilizing the gas flow 11 contains located along the gas flow means for normalizing the pressure of the gas 13 and means for normalizing the cross section of the gas stream 16. Here, the term “normalization” means bringing the flow parameters to predetermined values. When the gas passes through the means for normalizing the pressure of the gas 13 in the stream, the pressure is set at a predetermined level, and with the further passage of the gas through the means for normalizing the cross sections of the gas stream 16, the gas cross section is set at the predetermined level, as a result of which the gas flow rate at the outlet of the means for stabilization gas flow rate of gas 11 has a predetermined value, which is constant and depends on what values of the above parameters are configured means 13 and 16. The means for stabilizing the pressure 12 can be made in the form of a chamber with an inlet valve, which regulates the flow of gas into the said chamber depending on the pressure in it, thus maintaining the pressure in the chamber at a stable level. Also, standard pressure regulators, for example, the EAR series pressure regulator [Pneumatic equipment. Catalog 2002. Chelyabinsk: Autograph, 2001, p. 28]. The means for normalizing the gas flow cross section 16 can be made in the form of a membrane with a central hole, the size of which can be adjusted, or a Venturi device, or standard exhaust chokes such as GRE, GRU and others [Pneumatic automation. Catalog 1998/99, FESTO, 1998]. Since the volume of gas passing through the device per unit of time is maintained at a predetermined stable level, it is not necessary to measure it, it is only necessary to measure the operating time of the device.

After the device has worked for a certain time, the valve of the sampler 20 is closed, and the gas-permeable filter is removed from the cavity of the working chamber for analysis. In the case of microbiological control of compressed gas, the filter is placed in a nutrient medium for the corresponding microorganisms, they are grown under certain conditions, and colonies grown from microorganisms deposited on the filter are counted. The CFU / m ³ indicator is calculated by the formula X = k * N / (V * t), where X is the concentration of microorganisms per unit volume, N is the number of colonies grown on the filter, V is the volumetric gas flow rate (nameplate characteristic of the device), t is the sampling time (passing gas through a gas-permeable filter), k is the integral correction coefficient, taking into account both the difference between the properties (for example, viscosity) of the working gas and the corresponding characteristics of the gas used to calibrate the means to stabilize the gas flow, and the difference in conditions (for example atmosphere pressure), at which control is carried out from normal (P = 0.101325). Moreover, if the means for stabilizing the gas flow 11 is equipped with a temperature sensor 15, as shown in the drawing, the volumetric gas flow V can be brought to normal conditions (T = 293.15 K) for air, which will further increase the accuracy of the calculations. To determine the content of solids in a gas, the filter is subjected to either microscopy in an immersion liquid or gravimetric analysis. Since the device maintains the gas flow rate at a certain stable level, to calculate the concentration of suspended particles per unit volume during the analysis, it is necessary to measure only the operating time of the device.

As follows from the description of the device, the flow of compressed gas from its source passes directly into the working chamber and is fully filtered through a gas-permeable filter, which allows all particles present in the gas stream to be deposited on the said filter (with the right choice of pore or hole size). When determining the content of microorganisms in gases, the viability of these microorganisms (bacterial particles) is maintained, since the humidity in the gas stream does not change significantly, resulting in a high accuracy of determination of CFU / m ³ . Since the device operates with a stable controlled gas flow, when conducting analyzes, it is only necessary to measure the operating time of the device. The device is universal - with its help it is possible to determine the content of both microorganisms and mechanical solid particles in compressed gases.

Claims (13)

1. A device for determining the content of suspended particles in compressed gases, comprising a working chamber equipped with an inlet and an outlet, in the cavity of which there is installed a means for trapping suspended particles, characterized in that it is equipped with a means for stabilizing the gas flow, which is located after said working chamber the gas flow and which contains means for normalizing pressure and means for normalizing the cross section of the gas stream, and means for normalizing the cross section of the gas stream is installed after the means of normalization Bani pressure during the gas, and means for trapping particulate matter is in the form of the gas permeable filter that is installed so that the gas stream passes through the cavity of the working chamber from the inlet to the outlet through said filter. 2. The device according to claim 1, characterized in that the pressure standardization means is made in the form of a chamber equipped with an inlet and an outlet, at the inlet of which a valve is installed that regulates the flow of gas entering the chamber, depending on the pressure in it. 3. The device according to claim 1, characterized in that the means for normalizing the cross section of the gas stream is made in the form of a membrane with an opening, the size of which is adjustable. 4. The device according to claim 1, characterized in that the cavity of the working chamber is made in the form of a mating diffuser and a confuser. 5. The device according to claim 1, characterized in that the gas-permeable filter is installed in the cavity of the working chamber perpendicular to the gas flow at the junction of the diffuser and confuser. 6. The device according to claim 1, characterized in that the input of the working chamber is equipped with means for connecting to a source of compressed gases. 7. The device according to claim 1, characterized in that the gas-permeable filter is made porous. 8. The device according to claim 1, characterized in that the gas-permeable filter is mesh. 9. The device according to claim 1, characterized in that the gas-permeable filter is made in the form of a perforated plate. 10. The device according to claim 1, characterized in that the means for stabilizing the gas flow is equipped with a gas temperature sensor. 11. The device according to claim 1, characterized in that the gas temperature sensor is installed after the means for normalizing the gas pressure in the direction of its movement. 12. The device according to claim 1, characterized in that the means for stabilizing the gas flow is equipped with a noise muffler. 13. The device according to claim 1, characterized in that the gas permeable filter is provided with a gas permeable substrate.