PL185142B1 - Analyzer of the amount of coal in ash, especially carried in flue gas from dust furnaces - Google Patents

Abstract

An analyzer of carbon quantity in ash, especially entrained in exhaust gases from pulverized coal furnaces, having - a sampling assembly, fitted with a cycle connected in parallel to the gas emission port through a tangential inlet port and a middle outlet port, with a vacuum source built into the outlet port, especially in the form of an injector mounted on a nozzle of the outlet port inserted into the emission port, furthermore in this assembly the lower port of the cylinder is connected to a measuring cell equipped with a sight glass and a cleaning nozzle, connected via a controlled shut-off valve to the compressed air preparation station. - a measuring unit comprising an optical reflectometer equipped with a measuring head mounted in the axis of the viewing window and in the measuring chamber, and furthermore having a processor-based signalling control unit, characterised in that its measuring unit (B) is extended with a resistance measurement circuit, consisting of two electrodes (14, 15) built inside the measuring cell (7) and connected to a high voltage circuit, which is equipped with an ammeter (17) connected to the signalling control unit (C)

Description

The subject of the invention is an analyzer for the amount of coal in ash, in particular suspended in flue gases from pulverized furnaces in power plants or combined heat and power plants.

Analyzers are known which use the change of optical properties of an ash sample as a function of the amount of carbon present in it. For example, the analyzer presented in the Polish patent application no. 178 781 consists of three basic units: sampling, measurement, control and signaling. The sampling unit is equipped with a cyclone connected in parallel with a gas emission channel: a tangential inlet channel and a central outlet channel. At the end of the outlet channel introduced into the emission channel, an injection orifice is installed, causing the gas to flow through the cyclone. The precipitated dust falls through the bottom channel of the cyclone into a coaxially attached vertical discharge tube, defining the measuring cell. Measurement of the light intensity reflected from the sample surface is made through a flat sight glass that covers the lower end of the discharge tube with a gap between them. At the end of each measuring cycle, the cleaning nozzle tangentially directed into the gap between the sight glass and the discharge tube is connected by an electromagnetically controlled shut-off valve with the compressed air preparation station. The value of the light intensity reflected from the sample surface determined in the measuring electronics unit is transmitted to the control and signaling processor unit. The amount of coal is determined on the basis of the previously determined and entered into the computer characteristics of the dependence of the intensity of reflected light and the carbon content in the ash from the combustion of a given type of coal

In another analyzer, described in the Polish patent application No. 182 474, the plane of the sight glass is inclined with respect to the horizontal plane, the dust sample after the analysis is blown into the emission channel through a cyclone. The measurement of the reflected light intensity in the solution of the analyzers manufactured by the Danish company M & W Asketeknikten is carried out through a transparent wall of a glass drop tube, the lower end of which is closed with a cone with a cleaning nozzle.

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When using the optical method for determining the amount of carbon in the ash, each change of the coal grade must be accompanied by an appropriate correction of the measuring signal, resulting mainly from the strong influence of the chemical composition of the gangue on the ash color. Many power plants are supplied with coal from various mines, frequent changes of the type of coal at numerous measuring points make it very laborious to correct the analyzers.

The analyzer according to the invention has a structure similar to the above-described solutions, it has a cyclone sampling unit, a measuring unit with an optical reflectometer that determines - through the sight glass of the measuring cell - the intensity of light reflected from the ash surface, and a control and signaling unit. The essence of the solution lies in the fact that the measuring unit, apart from the optical reflectometer, has a resistance measurement system with two electrodes built inside the measuring cell and included in a high voltage circuit equipped with an ammeter. The measuring signal of the ammeter is fed to the control and signaling unit. The magnitude of the current flowing through the sample depends mainly on the carbon content in the ash.

Determining the result based on a digitally assisted analysis of the interdependence of data obtained from two measurement methods using significantly distant physical phenomena, allows for a significant increase in measurement accuracy and the introduction of an auto-correction of the result necessary when changing the type of coal burned. Moreover, the signal of the ammeter can also be used for diagnosing the operation of the electrostatic precipitator installed in the exhaust gas exhaust system.

It is advantageous if one of the electrodes has the form of a ring built circumferentially into the walls of the measuring cell, and the other, rod-shaped, is attached along the axis of the measuring cell. Such a structure ensures good ash flow conditions both in the sampling and emptying phase of the measuring cell.

The presented solution according to the invention ensures high measurement accuracy and eliminates the need to calibrate the analyzers after each change of the type of coal burned.

The analyzer according to the invention is presented with a description of an exemplary embodiment shown in the drawing in a schematic view.

The analyzer consists of three main units ⁷ : the sampling unit A, the measuring unit B and the control and signaling unit C. The sampling unit A has a cyclone 1 connected in parallel to the dust-laden gas emission duct 2 through a tangential inlet duct 3 and an upper exhaust duct 4. The gas flow through the cyclone 1 is initiated by the negative pressure caused by the work of the injection orifice 5 mounted in the outlet channel 4. The lower channel 6 of the cyclone 1 connects to the measuring cell 7, which is defined by the internal space of the tube embedded in the analyzer body. The lower end of the measuring cell 7 is covered with a flat sight glass 8 of the measuring unit B. A cleaning nozzle is led to the measuring cell 7, connected by an electromagnetic cut-off valve 9 to the compressed air preparation station 10. The supplied air is thoroughly cleaned. The analyzer measuring unit B includes an optical reflectometer and a resistance measurement system. Optical reflectometer is used to measure the intensity of infrared radiation reflected from the surface of the ash sample. It consists of lighting diodes 11, a detector 12 and a block of measuring electronics 13, the signal of which is fed to the control and signaling unit C. The resistance measurement system has two electrodes 14 and 15 built inside the measuring cell 7, connected to a DC high voltage circuit, equipped with a direct current source 16 and an ammeter 17, the measuring signal of which is transmitted to the control and signaling unit C and to the electrostatic precipitator diagnosis system not shown in the drawing. The electrode 14 has the form of a ring built in and flush with the inner surface of the measuring cell 7, the second electrode 15 is a bar fixed along the axis of the measuring cell 7. The control and signaling unit C is shorted by cable connections with the measuring unit B and the cut-off valve 9 controls the measuring process and signals the states emergency, determines the carbon content in the ash on the basis of measurement signals from the measuring electronics unit 13 and the ammeter 17 and archives the data.

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When using the optical method for determining the amount of carbon in the ash, each change of the coal grade must be accompanied by an appropriate correction of the measuring signal, resulting mainly from the strong influence of the chemical composition of the gangue on the ash color. Many power plants are supplied with coal from various mines, frequent changes of the type of coal at numerous measuring points make it very laborious to correct the analyzers.

The analyzer according to the invention has a structure similar to the above-described solutions, it has a cyclone sampling unit, a measuring unit with an optical reflectometer that determines - through the sight glass of the measuring cell - the intensity of light reflected from the ash surface, and a control and signaling unit. The essence of the solution lies in the fact that the measuring unit, apart from the optical reflectometer, has a resistance measurement system with two electrodes built inside the measuring cell and included in a high voltage circuit equipped with an ammeter. The measuring signal of the ammeter is fed to the control and signaling unit. The magnitude of the current flowing through the sample depends mainly on the carbon content in the ash.

Determining the result based on a digitally assisted analysis of the interdependence of data obtained from two measurement methods using significantly distant physical phenomena, allows for a significant increase in measurement accuracy and the introduction of an auto-correction of the result necessary when changing the type of coal burned. Moreover, the signal of the ammeter can also be used for diagnosing the operation of the electrostatic precipitator installed in the exhaust gas exhaust system.

It is advantageous if one of the electrodes is in the form of a ring built circumferentially into the walls of the measuring cell, and the other, rod-shaped, is attached along the axis of the measuring cell. Such a structure ensures good ash flow conditions both in the sampling and emptying phase of the measuring cell.

The presented solution according to the invention ensures high measurement accuracy and eliminates the need to calibrate the analyzers after each change of the type of coal burned.

The analyzer according to the invention is presented with a description of an exemplary embodiment shown in the drawing in a schematic view.

The analyzer consists of three main units: the sampling unit A, the measuring unit B and the control and signaling unit C. The sampling unit A has a cyclone 1 connected in parallel to the emission duct 2 of the dusty gas through the tangential inlet duct 3 and the upper outlet duct 4. The gas flow through the cyclone 1 is initiated by the negative pressure caused by the work of the injection group 5, mounted in the outlet channel 4. The bottom channel 6 of the cyclone 1 connects to the measuring cell 7, which is defined by the inner space of the tube embedded in the analyzer body. The lower end of the measuring cell 7 is covered with a flat sight glass 8 of the measuring unit B. A cleaning nozzle is led to the measuring cell 7, connected by an electromagnetic cut-off valve 9 to the compressed air preparation station 10. The supplied air is thoroughly cleaned. The analyzer measuring unit B includes an optical reflectometer and a resistance measurement system. Optical reflectometer is used to measure the intensity of infrared radiation reflected from the surface of the ash sample. It consists of lighting diodes 11, a detector 12 and a block of measuring electronics 13, the signal of which is fed to the control and signaling unit C. The resistance measurement system has two electrodes 14 and 15 built inside the measuring cell 7, connected to a DC high voltage circuit, equipped with a direct current source 16 and an ammeter 17, the measuring signal of which is transmitted to the control and signaling unit C and to the electrostatic precipitator diagnosis system not shown in the drawing. The electrode 14 has the form of a ring built in and flush with the inner surface of the measuring cell 7, the second electrode 15 is a bar fixed along the axis of the measuring cell 7. The control and signaling unit C is shorted by cable connections with the measuring unit B and the cut-off valve 9 controls the measuring process, signals emergency states , determines the carbon content in the ash on the basis of measurement signals from the measuring electronics unit 13 and the ammeter 17 and archives the data.

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Claims (2)

Patent claims 1.A analyzer for the amount of carbon in ash, especially suspended in flue gases from pulverized furnaces, having: - a sampling unit, equipped with a cyclone connected in parallel in the gas emission channel through the tangential inlet channel and the central outlet channel, with a vacuum source built in the outlet channel, in particular in the form of an injector mounted on the end of the outlet channel introduced into the emission channel, moreover, in which assembly the bottom channel of the cyclone is connected to a measuring cell equipped with a sight glass and a cleaning nozzle, connected by a controlled cut-off valve to the compressed air preparation station, - a measuring unit, including an optical reflectometer equipped with a measuring head mounted in the sight glass axis and a measuring electronics block, and also having a control and signaling processor unit, characterized in that its measuring unit (B) is extended with a resistance measuring system, consisting of two electrodes (14, 15) built inside the measuring cell (7) and connected to the high-voltage circuit, which is equipped with an ammeter (17) connected to the control and signaling unit (C). 2. The analyzer according to claim The method according to claim 1, characterized in that one of the electrodes (14) is in the form of a ring circumferentially built into the wall of the measuring cell (7), and the other (15) in the shape of a rod is fixed along the axis of the measuring cell (7). * * *