RU12860U1 - DEVICE FOR TAKING SAMPLES OF GAS-MOISTURE MOISTURE FROM HIGH-TEMPERATURE GAS FLOW - Google Patents

Abstract

1. A device for sampling gaseous moisture from a high-temperature gas stream, including a gas sampling tube having an inlet end for entering the gas duct through which the controlled stream flows, and an outlet end with a transition element for connecting a moisture trap, and a heating jacket surrounding a gas sampling tube, characterized in that the heating jacket is located along the gas sampling tube so that it heats a portion of it outside the gas duct and a transition element at the outlet end, in this case, the heating jacket is designed so that the gas sampling tube is heated to a temperature not less than the temperature of the controlled gas flow. 2. The device according to claim 1, characterized in that the device for trapping moisture is made in the form of three series-connected capacitors placed in heat-insulating flasks with cooling material, the last of which is connected to a sample filled vessel with indicator silica gel. 3. The device according to claim 1 or 2, characterized in that it includes a filter for trapping moisture drops connected to the inlet end of the gas sampling tube.

Description

The utility model relates to the field of environmental control, namely, devices for sampling from flows of a high-temperature gas-air mixture (controlled flows) in the exhaust channels of air pollution sources (ducts) to determine the content of gaseous moisture in a gas-fired mixture emitted into the atmosphere as one of its characteristic parameters . The device can be used in the inventory of emissions of pollutants into the atmosphere and environmental monitoring of sources of air pollution in any industry.

One of the key conditions that must be ensured when taking samples from controlled streams to determine the gaseous moisture content is the exclusion of moisture during the passage of the gas-produced mixture (sample) from the controlled stream to the moisture collecting device, for example, a condenser of the analytical part of the equipment (GOST 17.2.4.08-90. Environmental protection. Atmosphere. Methods for determining the humidity of gas and dust streams emanating from stationary sources of pollution.)

A device for sampling high-temperature dusty gases from controlled streams (Pat. Ki 2050535, G 01 N 1/24, 3. 29.12.92, op. 20.12.95 Bull. Go 35), including a sampling (sampling) tube surrounded by a heated for example, a steam jacket and coupled with traps to collect sample components; dust particles, vapors of elemental metals, moisture.

The disadvantage of this device is that the condensation of gaseous moisture during passage of the sample to the traps is not excluded, that is, there is an incomplete ingress of gaseous moisture into the traps. In this case, suspended traces fall into traps along with condensed moisture, which greatly complicates the determination of gaseous moisture content. In addition, the device does not provide control over the completeness of moisture capture, i.e. when used, it is not guaranteed that all gaseous moisture is trapped. Thus, the accuracy of determining the content of gaseous moisture in a controlled flow with the help of such a sampling device is not ensured.

There is another device for sampling from a gas stream (Pat. Ki 2042940, G 01 N 1/22, 3.01.02.93, op. 08.27.95 Bull. No. 24), including a filter placed inside the duct connected by a thermal hose to the gas analysis complex. A thermo hose is a sampling tube enclosed in a thermally insulating sheath, including a heating element. The disadvantage of this device is that it also does not

provides zero collection of gaseous moisture in a controlled flow. In addition, the device also does not provide control over the completeness of moisture capture, i.e. when used, it is not guaranteed that all gaseous moisture is trapped. Also, this device at 100% relative humidity of the controlled flow does not prevent the entry into the gas analysis complex, in the gaseous form, of that part of the moisture that is in the liquid-droplet form in the controlled flow. This leads to an increase in the error in determining the content of gaseous moisture in a controlled flow. Thus, this device when used to determine the gaseous moisture content in a controlled stream does not give the desired result.

These disadvantages are eliminated in the proposed utility model. It is a device for sampling gaseous moisture from a high-temperature gas stream, including a gas sampling tube having an inlet end for entering the gas duct, and an outlet end with a transition element for connecting a moisture trap, as well as a heating jacket surrounding the gas sampling tube, distinguished from the one known by the fact that the heating jacket is located along the gas sampling tube so that it heats the pipe section located outside the gas duct and the transition element at the output end, at this

the heating jacket is designed to heat the gas sampling tube to a temperature not less than the temperature of the controlled gas stream.

In addition, the proposed device may contain a device for trapping moisture, made in the form of three series-connected capacitors, placed in heat-insulating flasks with cooling material, the last of which is connected to a sample passage through a vessel filled with indicator silica gel.

Also, the proposed device may include a filter for trapping moisture drops, connected to the inlet end of the gas sampling tube.

The set of features of the proposed utility model is not currently known from the prior art. The differences of the proposed device from the known ones ensure the completeness of the collection of gaseous moisture from the controlled flow, since the loss of gaseous moisture from the sample during transportation along the gas sampling tube is excluded. This provides a solution to the problem with maximum effect. This is achieved by creating different thermal regimes in different sections of the sampling tube: the portion of the sampling tube (its length is usually not less than 5 cm) inside the duct is isothermal to it; part of the sampling tube located outside the duct and part of the inlet pipe

moisture trapping devices (due to the location of the transition element of the outlet end of the gas sampling tube inside the heating zone) is not maintained at a temperature not lower than the temperature of the controlled flow. This ensures maximum preservation of the gaseous moisture content during the passage of the sample from the controlled flow through the sampling tube to the capacitors, and thereby, high accuracy in determining its content in the controlled flow.

In the case when the device for collecting moisture is made, as described above, it is very easy to control the completeness of moisture collection in the capacitors and fixation of the end of the process by changing the color of the indicator silica gel located at the output of the device. All this ensures, ultimately, the completeness of the collection of gaseous moisture from the sample and, thereby, high accuracy of the result. A device for collecting moisture in the form of three vessels placed in insulating flasks with, for example, ice, is very simple in design, convenient to operate.

B, when a filter for trapping moisture drops is connected at the inlet of the entire device, moisture that is in the sample stream in the controlled stream in the liquid-droplet phase is prevented from entering the sample, and this ensures the maximum accuracy of the result at any relative humidity of the controlled stream.

d t g2 /

Figure 1 shows a schematic representation of one of the possible options for a specific implementation of the product, which reveals the essence of the proposed solution.

The device comprises a sampling tube 1, which includes an unheated section 2 and a heated section 3; the unheated portion of the sampling tube can be extended by removable elbows 4 depending on the diameter and wall thickness of the duct; filter 5 is attached to the inlet end of the sampling tube. Filter 5 serves to trap dust particles and, in the case where the humidity of the controlled flow exceeds 100%, drops of moisture. The output end of the heated portion 3 of the sampling tube has a transition element 6 in the form of a conical expansion located inside the heating zone. The pipe 7 of the moisture condenser 8 is connected to the sampling tube 1 by a gasket-free transition and secured with a screw 9. The heating jacket consists of an internal insulating tube 10 that is tightly attached to the narzok surface of the 2nd (heated) part of the sampling tube; an electric heating element 11, the energy-generating surface of which is evenly distributed along the length of the tube 10; a heat-insulating shell 12, protected externally and from the ends by a metal casing 13. Inside the heat-insulating shell 12 there is a temperature sensor 14 connected to a thermal relay 15. Moisture condensers 8, 16 and 17 and a vessel 18 filled with indicator silica gel are connected in series with a 6 sampling tube. Capacitors 8, 16 and 17 are immersed in

heat-insulating flasks 19, 20 and 21 with ice, located in the container 22.

The sampling tube, filter housing and moisture condenser 8 are made of stainless corrosion-resistant steel. As a heating element, a conventional electric heating coil can be used, which is protected along the length of the tube by electrical insulation; as a temperature regulator, consisting of a temperature sensor and a thermal relay, a temperature regulator used in household appliances, for example, in kitchen electrical appliances, can be used, and as insulating flasks - insulating flasks of household thermoses.

The proposed device operates as follows. After the device is assembled, an unheated lock 2 of the sampling tube 1 is inserted into the flue so that the gap between the heating switch and the outer surface of the flue wall does not exceed 0.5 cm. The electric heating element is connected to a 220 V electric power source; the temperature indicator of the temperature controller relay is set to a value corresponding to the temperature of the monitored flow. After heating the heated area for 2-3 minutes, an aspiration device is turned on, connected to the outlet of the vessel 18, which pumps the sample through the entire gas supply path at a speed of 0.5

9E / - J3I

1 L / min up to 5.0 l / min (depending on the expected mix)

moisture in a controlled note).

Particulate matter and water droplets are retained by the filter. Since the temperature of the sample at the beginning of the first (unheated) portion of the sampling tube (including the filter) is the same as the temperature of the controlled flow, the relative humidity of the gas-air mixture in the sample is the same as in the gas duct, therefore condensation of moisture or its evaporation (in the case of flow humidity in gas duct above 100%) on the filter and in that part of the sampling tube, which is in a controlled stream, does not occur. In the sample tube section adjacent to the heating jacket, which is located between the controlled flow and the heating jacket (duct wall plus the natural gap between the duct wall and the heating jacket of the device), the sample temperature is not lower than at the beginning (since the heat influx from the heating jacket propagating through a metal sampling tube (due to its 20-30 degree overheating inside the heated jacket) exceeds its ejection from the tube surface in this interval due to t of convective transfer under conditions of a very low speed of the external flow and its low turbulence (due to the narrow gap between the heating jacket and the outer surface of the duct wall).

9 / - // nf

8 In the area of the sampling tube 2 located in the heating zone, and on

the initial section of the pipe 7 of the moisture condenser 8, also falling into this zone, the temperature of the sample exceeds the temperature of the controlled flow. Thus, on the entire path of the sample from the controlled flow to the cooled part of the pipe 7, its temperature is not lower than in the controlled flow, and moisture condensation does not occur.

Moisture condensation begins only after the gas-air mixture enters the unheated part of the condenser pipe. Condensed moisture is collected in moisture condensers 8, 16, 17 and in a vessel 18 filled with indicator silica gel, which changes color when moisture enters it. The color constancy of the indicator silica gel at the outlet of the vessel 18 indicates the completeness of moisture capture in the capacitors 8,16,17 and in the initial section of the vessel 18.

But at the end of sampling, moisture condensers 8, 16, 17 and into vessel 18 are disconnected from the system, wiped dry and placed in a sealed container for transportation to the laboratory for weighing.

It is obvious that the proposed device design does not require any new or special means for its implementation. In addition, this device, relative to the used known devices, is cheaper, and the used structural elements are publicly available. Thus, the proposed device is quite simple in design and manufacturing and provides high accuracy in determining moisture

/ U / "/

9 high-temperature gas flows of moisture of a korgfolirovanny Tsotok. for all values of relative

Claims (3)

1. A device for sampling gaseous moisture from a high-temperature gas stream, including a gas sampling tube having an inlet end for entering the gas duct through which the controlled stream flows, and an outlet end with a transition element for connecting a moisture trap, and a heating jacket surrounding a gas sampling tube, characterized in that the heating jacket is located along the gas sampling tube so that it heats a portion of it outside the gas duct and a transition element at the outlet end, in this case, the heating jacket is designed to heat the gas sampling tube to a temperature not less than the temperature of the controlled gas stream.  2. The device according to claim 1, characterized in that the device for trapping moisture is made in the form of three series-connected capacitors placed in heat-insulating flasks with cooling material, the last of which is connected to a sample filled vessel with indicator silica gel. 3. The device according to claim 1 or 2, characterized in that it includes a filter for trapping moisture drops connected to the inlet end of the gas sampling tube.