SU714100A1 - Method of monitoring burner flame pesence - Google Patents

Description

; The invention relates to a power system and can be used to control and control the operation of burners. There is a known method of monitoring the presence of a burner flame by its radiation, measured with a radiation sensor, sighted in a specific, controlled area. flame 11. In the known method, the presence of a flame of a controlled burner is judged on the basis of the signal being exceeded by the average value of the radiation sensor signal of a given setpoint, and ensuring the selectivity of the control, i.e. The detuning from the influence of the radiation of the flame of other burners is achieved by sighting the radiation sensor in a specific flame zone under a given angle. The disadvantages of this method are associated with the limited range of loads and modes of the unit, in which the selectivity of control is reliably ensured. As a rule for furnaces of powerful energy boilers equipped with a large number of burners, the known method can be used only at the stage of ignition of burners. With a high level of heat load and the inclusion of a large number of burners, the zone of the controlled firing when the burner is turned off is filled with hot gases, as a result, the background radiation level approaches a predetermined setpoint and ensuring display selectivity is significantly more difficult. The closest to the invention in technical terms and the effect achieved is a method of controlling the presence of a burner flame by radiation, measured by two sensors, sighted in one zone of a controlled flame, by forming the difference of the signals issued by the sensors, and comparing it with a predetermined setting 2. The disadvantage of the known The method consists in that, in this case, selectivity is achieved by significantly complicating the sighting and adjustment of sensors, in particular, by choosing a narrow spectral range. The purpose of the invention was to increase the reliability of controlling the flame of a single burner. For this purpose, the values of the second setpoint are additionally set and the signal of one of the sensors is compared with it, and the assessment of the presence of a flame is made on the basis of simultaneous observation of the conditions of the difference between the signals of the value of the first setpoint and the value of the second setting exceeding the compared sensor signal. FIG. 1 shows a printable scheme; in fig. 2 - functional converter circuits. ; Two identical radiation sensors 1 and 2 kfig. 1), for example, radiation or photoelectric pyrometry, are mounted on the burner and endorsed in the same area A of the radiating surface of the controlled flame. Cigals Ej and Ej ot sensors arrive at the same amplifiers 3 and 4, after which in the adder 5 their difference dB Ej-Ea is formed. Signals Ej and DE come on. converters 6 and 7. Signals -1 and the outputs of the converters are fed to threshold devices 8 and 9, where they are compared with the settings Yg, (and Y. The signal from the output of the device 8 does not directly go to the input of the logic element 10 (I), and the signal from the output of the device 9 enters the input of that element 10 through the logic element 11 (. (NOT). The output of element 10 is directly connected to the upstream protection and alarm system 12. Radiation flows to the same sensors 1 and 2 from the same The same area A controlled flame, about the same. Therefore, the signals Ej and Ej of sensors 1 and 2, in the presence of a flame of a controlled burner, should be close in magnitude to both constant and variable voltage, and their difference DЕ should be close to zero. When the controlled burner is turned off, its flame goes out and goes down) Other emitters, radiation flows to sensors 1 and 2 from different regions B and C of other emitters. Therefore, the signals EI and EJ should differ significantly in terms of the constant and (or) variable components, and in the general case both . In this case, the values of the constant LU and variable LU components may be different in different cases depending on the number, location and performance of the included burners, the total load of the combustion chamber, the type of fuel and other factors. It is important that the sign and / or characterizes the absence of a controlled flame.:.,: The only case where this condition may not be fulfilled is the case of a cold or very dark firebox, when all or almost all burners are turned off and DE

714,100 close to zero. Therefore, the sign ЕЕ i О should be added with the sign of presence, (HAH) E, Vg. In this connection, the information on the presence of the flame of the controlled burner is formed as follows. In converter 7 (phot. 2), the value of DE is divided with the help of a band-pass 13 and a smoothing 14 filters into components DE and DE, the values characterizing these components are measured (for example, DE may have an effective amplitude of pulsations in the extended frequency band, measured detected by the detector 15 and the damper 16) and both signals after the threshold devices 9 arrive at the logical element 17 OR. (In specific cases, only x of the bottom can be used). The structure of the converter 6 is similar: signal E | divided by Eia and E, / are measured, the values of these components and after the threshold devices both signals are sent to the logic element 10 I. Output device 12 is triggered if the following conditions are simultaneously fulfilled: GE;., (2) Hardware implementation The proposed method may be different (Fig. 2): a) a simplified version involves the use of two measuring channels E. Xm D.E (L IN / f) DEB) to increase reliability, you can add a channel Deg: (DE,., Y , LIE) c) in the case when the total number of burners is large, for example more than eight, you can use additional channel E ,:. (), leader d) in the case when the reliability of radiation sensors 1 and 2 themselves is low, for example when using photoelectric sensors .. and E, 7 Y, cov, the channels can be duplicated by identical channels .. .2 With threshold devices 18. In addition, the value of AE can be used to detect the failure of one of the sensors 1 or 2, if DE-7. 7 where Ud Be - The maximum possible value of the DEG in any operating mode of the unit, and intact sensors 1 and 2, using the threshold device 19 and the sensor alarm device of the sensor 20.

Claims (2)

1.Ermakov V.S. Electoral control of individual torches during the firing of powerful boilers. Automatic and automated control systems in power engineering M., publishing house ENIN, 1975, vol. 37, p. 3 2. US patent number 3689773, cd. 250-217, publ. 1972. - / / J P. ff 16 /four  lFig. 2 viX / / fltrr / niiJ /eight ..i.ii - 11 II .j Iv.