RU2606099C2 - Method for measurement of ash impurities with gas flow and device therefor - Google Patents

Abstract

FIELD: measurement technology.

SUBSTANCE: group of inventions relates to methods of measuring volume or mass fraction of fluid and impurities in gas flow, as well as to selection of sample for determining of grain-size composition of mechanical impurities. Method of measurement of ash impurities with gas flow comprises isokinetic sampling of gas flow from main part, its supply to separation, accumulation and measurement of separated impurities. At that, purified gas flow is returned to main gas flow in low pressure point provided for point selection by partial closing of main gas flow shut-off element. Device for implementing above method involves probe of isokinetic sampling of gas, separation device for collection and separation of dropping liquid and mechanical impurities, device for measuring flow rate of withdrawn gas and control device mounted on line of gas flow for point selection of analysed gas, after which purified analysed gas is fed into gas flow. Control device provides isokineticity of gas flow withdrawn by control of hydraulic resistance of main gas flow for point selection, as well as additional control of pressure drop on device after selection.

EFFECT: higher efficiency of separation, environmental friendliness of method and reduced number of process sections.

5 cl, 5 dwg

Description

The group of inventions relates to methods for measuring the volumetric or mass fraction of liquid and impurities in front of equipment; measurements of fluid entrainment after equipment; measuring the distribution of fluid over the cross section of the pipeline; measuring the mass fraction and percentage of solids before and after equipment; sampling to determine the particle size distribution of solids.

A known method of measuring the entrainment of the dispersed phase in a gas stream and a device for its implementation (patent No. 2396553 from 06.22.2009, G01N 25/26 and patent No. 2386123 from 10.11.2008, G01N 25/56, as well as the "Method and device for measuring the entrainment of drip liquids in gas treatment plants ”authors: MN Akhlyamov, F. A. Baiguzin, I. M. Shigapov, G. Kh. . 79 ÷ 81), including passing at a pressure, temperature and velocity of the gas stream through the filter cartridge a certain volume of gas sample with subsequent determination the weight of the filter cartridge due to the deposition of the dispersed phase, the volume of the gas sample is taken from the gas stream through a sampling probe. Installation for implementing the method of measuring the entrainment of the dispersed phase in the gas stream, containing a filter cartridge, a constant gas flow controller at pressure, temperature and speed in the installation system, equal to pressure, temperature and gas flow rate. The constant gas flow controller is made in the form of a block with a set of calibrated critical nozzles.

The disadvantages of these methods are: the release of the separated test gas into the atmosphere (to the torch), incorrect stepwise measurement of the test gas.

A known method and device for measuring the entrainment of impurities with gas (prototype), including a moving device with a probe for sampling, a device for separating droplet liquid or mechanical impurities from a gas stream, collecting and measuring the volume of separated liquid (solids) and the volume of purified gas, including a separator separation of impurities, measured capacity for impurities; gas volumetric flow meter, control valves (G.A. Lanchakov, A.N. Kulkov, G.K. Siebert, "Technological processes for the preparation of natural gas and methods for calculating equipment", Moscow, NEDRA, 2000, pp. 207 ÷ 220) .

The main disadvantages of this method and device are the discharge of a large amount of the test gas “on a candle” - into the atmosphere (with small entrainment of liquids with gas up to three days or more), which violates the environment, leading to penalties.

Also known is a device for cleaning a gas stream from liquid particles (RF patent No. 2022618, IPC ⁶ B01D 45/12, B04C 5/08), comprising a cylindrical body with a tangential nozzle for introducing a stream to be cleaned and spiral grooves directed towards the swirl of the flow on the inner surface along the entire height, the collection of the separated phase, and the lower part of the housing is made conical with cuts along the generatrix at the lower output end, into which the grooves are led.

The disadvantage of this device is: low filtration efficiency, for example, oil - (70 ÷ 90)%.

A horizontal separator is known (RF patent No. 2334542 dated 02/07/2007, B01D 45/08, B01J 19/32), which with a gas velocity factor equal to or less than two (Ф <2 = W · ρ ^0.5 , where W - the gas flow velocity in the operating state, ρ is the gas flow density kg / m ³ ) provides almost liquid ablation, close to zero (traces). The separator is made of packages with contact separation elements installed in the housing perpendicular to the horizontal axis of the separator, while packages of porous sheets with inclined corrugations are installed at the gas inlet, packages of sheets with inclined porous protrusions are installed at the gas outlet, and adjacent packages are rotated around a horizontal the axis of the apparatus in different directions relative to each other, the angle of rotation of each package (25 ÷ 35) ^° . Corrugations and protrusions of adjacent sheets intersect at an acute angle.

The disadvantage of this device is the need to release a large amount of separated gas into the atmosphere.

A single technical result of the group of inventions is to increase the separation efficiency and environmental friendliness of the method, reducing the number of technological sections.

A single technical result in the implementation of the group of inventions on the subject - the method - is achieved by the fact that in the method of measuring the entrainment of impurities with a gas stream, including isokinetic selection of a portion of the gas stream from the main one, supplying it for separation, accumulation and measurement of the separated impurities, the purified gas stream is returned to the main gas stream to a point of reduced pressure, organized behind the sampling point by partially blocking the main gas stream by a shut-off body, that the speed of the studied gas stream is set equal to the pressure drops across the separator and the shut-off element or the speed of the investigated gas stream is set by the flow rate of the selected gas stream for separation.

A single technical result when implementing a group of inventions on an object - a device - is achieved by the fact that the system for measuring impurities in the gas stream, including a probe for isokinetic sampling of gas, a separation device for collecting and separating droplet liquid and mechanical impurities, a device for measuring the flow rate of the sampled gas, a regulating device, installed on the gas flow line behind the sampling point of the test gas, after which the purified test gas is fed into the gas stream, while the control device isokinetic effectiveness to bleed gas to study the regulation of the hydraulic flow resistance for the main gas flow tapping point that the control device provides for isokinetic bleed gas stream further study the regulation of the differential pressure on the device after sampling.

The implementation of reducing the pressure on the gas stream line behind the sampling point by the control device for gas separation ensured the possibility of the compressor supplying the separated gas stream and eliminating the discharge of the separated gas "to the candle" (into the atmosphere), regulating the pressure drop across the stream after sampling and the device provided the possibility of isokinetic selection gas flow for separation.

The authors are not aware of methods for measuring the entrainment of impurities with a gas stream and devices for its implementation, in which the separation of the test gas would be achieved in a similar way.

In FIG. 1 and FIG. 2 shows a diagram of the process according to the proposed method with the process of setting the flow rate of gas taken for separation, the same using a pressure differential meter on the source gas supply line and on the gas extraction line for separation or metering and establishing the required isokinetic separation gas flow rate by the gas meter during regulation expenses by a gate or a gate valve.

In FIG. 3-4 shows a separator of a liquid ablation meter.

In FIG. 5 shows a separation structured nozzle.

In FIG. 1 shows a diagram of the process according to the proposed method with the process of setting the flow rate of gas taken for separation using a differential pressure meter on the source gas supply line and on the gas extraction line for separation.

An object according to the method of FIG. 1 includes:

- feed gas supply line 1;

- probe sampling 2 from line 1;

- separator 3 separating impurities from the gas stream entering through the probe 2;

- measured capacity for impurities 4;

- differential pressure meter 5 (gas volumetric flow meter);

- control valves 6 (gate) for regulating the gas flow with impurities in the separation (by covering the gate, increase the selection of gas for separation);

- shutoff valves 7 to turn off the impurity meter - when closed.

The flow of the test gas G ₀ (Fig. 1) according to the proposed method is fed through the feed gas supply line 1 (pipeline) for processing, from which part of the gas is isokinetically taken (stream g ₀ ) at a temperature and pressure in the pipeline by sampling probe 2, while the equality of velocities in the pipeline and in the probe ensure the equality of the hydraulic resistance of the pipeline between the gas sampling points on the differential pressure meter (differential pressure meter 5) and the hydraulic resistance of the separated line with the separator 3 of the impurity compartment from a gas stream.

The volume of impurities, for example, liquid and mechanical impurities, or their mass for a certain time, is collected and measured in a measuring tank for impurities 4. The number of measurements is set to at least three, while the gain or addition of volume or mass per unit time should be almost the same.

In FIG. 2 shows a diagram of the process according to the proposed method with the process of setting the flow rate of gas taken for separation by a meter for measuring the flow rate of separation gas.

An object according to the method of FIG. 2 includes:

- feed gas supply line 1;

- probe sampling 2 from line 1;

- separator 3 separating impurities from the gas stream entering through the probe 2;

- measured capacity for impurities 4;

- gas flow meter 5, taken for separation (gas volumetric flow meter);

- control valves 6 (gate) for regulating the gas flow with impurities in the separation (by covering the gate 6, increase the selection of gas for separation);

- shutoff valves 7 to turn off the impurity meter - when closed.

The flow of the test gas G ₀ (Fig. 2) according to the proposed method is fed through the feed gas supply line 1 (pipeline) for processing, from where a portion of the gas (stream g ₀ ) is isokinetically taken with the sampling probe 2 at a temperature and pressure in the pipeline, while the equality of velocities in the pipeline and in the probe provide for the gas flow meter 5, taken for separation (gas volumetric flow meter).

The volume of impurities or their mass for a certain time is collected and measured in a volumetric container for impurities 4. The number of measurements is set to at least three, while the gain or addition of volume or mass per unit time should be almost the same.

In FIG. 3 shows a separator 3 separating impurities from the gas stream into which the test gas is fed through the inertial separation unit 7 (Figs. 3, 4), while (80 ÷ 90)% of the impurities are separated on it.

The residual content of impurities is separated on the separation structured nozzles 8 (Fig. 3 ÷ 5) before the impurities are carried out per cubic meter of purified gas less than 5 mg / m ³ , which allows the purified gas to be returned to the gas pipeline or technology in almost any conditions.

In the test gas, a quantitative measurement is made:

- impurities and liquids, as well as only liquids in a volumetric way visually in a calibrated measuring tank;

- impurities and liquids, as well as only liquids in bulk quantities, are made by weighing a measured capacity 4 before the study and after the study when measuring the amount of gas passed through for a certain period of time with equal pressures and temperatures of the source and test gas;

- in addition, the volume of a stable liquid weathered up to atmospheric pressure can be measured by connecting the measuring tank to the atmosphere;

- the volume and weight of mechanical impurities is determined by filtering impurities through the filter, drying the filter and determining its weight gain.

An example of the implementation of the measurement of impurities.

1. A standard device in a running installation measures the amount of feed gas G ₀ passing through the feed gas supply line 1 (pipeline) under operating conditions.

2. The volumetric gas flow rate g _{0 is} calculated, which must be passed through a separator 3 separating impurities from the gas stream.

g ₀ = G ₀ ÷ f / F,

where f is the cross-sectional area of the intake probe channel, F is the living cross-sectional area of the pipeline from which the test gas is taken.

3. The gas flow rate g _{0 is set} (according to the gas flow meter 5 or according to the equality of the differential pressure readings on the differential pressure gauges) to the separator 3 for separating impurities from the gas stream with the open source gas supply line 1, by covering the control valves 6.

4. Visually measured the volume of separated impurities in the measuring tank 4.

5. When using a mass flow meter measuring the test gas, its mass flow rate is determined.

6. When selecting the separated impurities from the measuring tank 4 in the laboratory measuring tank, it is possible to measure the volume of degassed liquid, as well as measure the amount of solids.

Thus, the proposed method and device for its implementation achieved a single technical result, which consists in increasing the efficiency of separation and environmental friendliness of the method, reducing the number of technological sections.

Claims (5)

1. A method of measuring the entrainment of impurities with a gas stream, including isokinetic selection of a part of the gas stream from the main one, feeding it for separation, accumulation and measurement of the separated impurities, characterized in that the purified gas stream is returned to the main gas stream to a reduced pressure point arranged behind the point selection by partial closure of the main gas stream by the shutoff body. 2. The method of measuring the entrainment of impurities with a gas stream according to claim 1, characterized in that the speed of the investigated gas stream is established by the equality of the pressure drops across the separator and the shut-off element. 3. The method of measuring the entrainment of impurities with a gas stream according to claim 1, characterized in that the speed of the investigated gas stream is set by the flow rate of the selected gas stream for separation. 4. A device for measuring the entrainment of impurities with a gas stream, including a probe for isokinetic sampling of gas, a separation device for collecting and separating droplet liquid and mechanical impurities, a device for measuring the flow rate of the sampled gas, a regulating device installed on the gas stream line behind the sampling point for the test gas, after which a purified test gas is fed into the gas stream, characterized in that the isokineticity of the gas stream selected for the study is established by adjusting the hydraulic resistance Phenomenon of the main gas stream behind the sampling point. 5. The device for measuring the entrainment of impurities with a gas stream according to claim 4, characterized in that the isokineticity of the gas stream selected for investigation is established by controlling the pressure drop across the device after selection.