RU2488043C1 - Adaptive device of burner flame monitoring - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: device comprising a photo diode, an amplifier-converter and an analyser is added with a circuit of normalisation of the analyser input signal. The normalisation circuit comprises an integrator. The amplifier-converter is made with the possibility of separation of a variable component in the photo diode signal, its strip amplification and single-sided limitation and fixed shift of the potential level of the input signal of the analyser, the normalisation circuit is made as capable of elimination of deviations of the time-average value of the input analyser signal from the normal signal.

EFFECT: invention increased reliability of selective monitoring of a single burner flare with expansion of the range of burnt fuel types.

2 cl, 4 dwg

Description

The invention relates to devices for controlling and regulating combustion processes using devices sensitive to thermal changes and including photosensitive elements. The scope of the invention is the automatic control of the flame in various fire engineering installations, and mainly the control of the flame of a single burner in the combustion chamber (furnace) of an energy or industrial steam generator (boiler) with two or more burners (in particular, with side and counter-directed burners ), especially in the case of alternating combustion of various types of fuel.

To protect the boiler, as well as to automate its start-up, selective control of both the fact of occurrence and the fact of the extinction of the torch of each individual burner is necessary. Such control is necessary to prevent explosive emergencies due to the flow of non-flammable fuel into the combustion chamber (through a burner without a flame).

The difficulty in detecting the presence (absence) of a torch in a controlled burner is due to the fact that the torch of a single burner in the furnace is not a point source of light, occupying a significant amount, torches can penetrate each other. In addition, in the total radiation of the furnace there is a contribution from the radiation of the surfaces bounding it. Therefore, in the general case, when the torch of the controlled burner disappears, the luminescence observed in the sight pipe through which the radiation of this burner is directed to the photosensitive element does not disappear, and the magnitude of the decrease in this luminescence may be insignificant.

The use of various types of combustible fuel can, in the general case, entail the need to change the corresponding settings of each flame control device (before the start of operation or in its process) and even its replacement.

A device for the selective control of the flame of a burner in the combustion chamber of a fire-fighting installation (RF patent 2121110, IPC6 F23N 5/08, publ. 10/27/1998), containing a series-connected photoelectric sensor, a conversion circuit for the output signal of this sensor, including an amplifier, and an output signal processing channel conversion schemes. The disadvantages of this device are the significant likelihood of the formation of a false signal about the presence of a torch due to the influence of radiation from other burners and the walls of the furnace, as well as the inability to exclude the effects of aging of the photodetector and changes in the transparency of its light path, which additionally requires a spectral filter.

A device for controlling the presence of a torch burner (RF patent 2388969, IPC6 F23N 5/08, publ. 05/10/2010, bull. No. 13), containing a series-connected photoelectric sensor, a sensor signal conversion system including an amplifier, and processing channels of the output signal of the conversion system . The disadvantage of this device is the need to use (for its operation) information on the status of valves on the fuel supply line to the burner. This leads to a significant complication of the functional and electrical circuits of the device.

A flame monitoring device is known (RF patent 2319900, IPC6 F23N 5/08, publ. March 20, 2008, bull. No. 8), comprising a photodetector (photodiode) connected in series, a photodetector signal converter and a converter output signal processing channel (analyzer). The disadvantage of this device is that among the known destabilizing factors, only the aging of the photodetector and the decrease in the transparency of its light path are taken into account, and not according to the actual change, but according to the accepted (normative) dependence on the duration (time) of operation.

A common drawback of the known flame control devices is the difficulty of operational control of the multi-burner boiler ignition process due to the need for manual adjustment to obtain the optimal level of the response threshold for each device of all boiler burners (in particular, due to the dependence of the signal level on the type of fuel burned), which requires considerable time .

It should be noted that the ability to configure the flame control device for operation in a wide range of the light flux entering the photodiode (i.e., for different types of fuel) is also limited by the non-uniformity of the load characteristic of the photodiodes (in particular, the FD-256 photodiode). With an increase in the luminous flux (from zero), the output signal of the photodiode at a constant load first increases and then falls, while the position of the maximum of the output signal with an increase in load shifts to lower values of the luminous flux. However, for the correct functioning of the control device, a positive correlation of the luminous flux to the photodiode and the output signal of the latter is required (operation within the upstream portion of the load characteristic of the photodiode).

The problem solved by the invention is to increase the reliability of the control flame of a single burner by increasing the selectivity of control while expanding the range of types of fuel burned, and also - simplifying the device by using only a light signal without involving other information.

In the implementation of the invention can be obtained, in particular, the following technical results: firstly, a decrease in the optimal threshold level of operation of the monitoring device; secondly, reducing the influence on the reliability of the output signal of the device for monitoring resource changes and operational deviations of the device and the furnace; thirdly, eliminating the need for manual adjustments and switching during operation of the control device; fourthly, increased noise immunity.

As a solution to the problem, which allows achieving an effect with the indicated characteristics, an adaptive burner flame control device is proposed, which contains a series-connected photodiode, an amplifier-converter, and an analyzer. Unlike the prototype, the proposed device is additionally equipped with a circuit for normalizing the input signal of the analyzer.

The normalization circuit contains an integrator, the integrating input of which is connected to the output of the amplifier-converter, and the reference input is connected to the output of the normal signal source, and an adjustable element connected to the output of this integrator is configured to change its active resistance under the action of the output signal of the specified integrator and connected to the input of the amplifier-converter with the ability to change its input resistance.

At the same time, the converter amplifier is capable of isolating the variable component of the output signal of the photodiode, its band gain and one-sided limitation and a fixed shift of the potential level of the analyzer input signal, and the normalization circuit is capable of eliminating the deviations of the average time value of the analyzer input signal from the normal signal.

The analyzer is made in the form of series-connected first and second integrators and a comparator. The reference input of the comparator is connected to its output, the reference input of the second analyzer integrator is connected to the output of the normal signal source, and the reference input of the first analyzer integrator is connected to the output of the comparator with the possibility of generating a reference signal equal to a part of the output signal of the comparator. The integration time of the first analyzer integrator is less than that of the second analyzer integrator, and the integration time of the latter is less than the time constant of the process of approximating the analyzer's average input signal to a normal signal.

In a private version, an adjustable element with the possibility of changing its active resistance can be made in the form of an n-p-n bipolar transistor, the emitter and collector of which are connected to the input terminals of the amplifier-converter, and the base is connected to the output of the integrator of the normalization circuit.

The proposed adaptive device for monitoring the flame of a burner (in a private version) is illustrated by the drawings:

Figure 1 is a functional diagram of a control device;

Figure 2 - schematic diagrams of the signal of the photodiode and the output signal of the amplifier-Converter during adaptation after the disappearance of the flame;

Figure 3 - plot of the output signal of the integrator of the normalization circuit and the average time output signal of the amplifier-Converter during adaptation after the disappearance of the flame (the first part corresponds to the initial time interval, and the second to the intermediate);

Figure 4 - plot signals on the elements of the analyzer during adaptation after the disappearance of the torch flame of the burner (solid line is the signal being processed, the dotted line is the reference signal, E is the supply voltage).

The adaptive burner flame control device contains a series-connected photodiode 1, an amplifier-converter 2 of the output signal of the photodiode 1 and an analyzer of the output signal of the amplifier-converter 2. The output of the photodiode 1 is connected to the input of the amplifier-converter 2, and the output of the latter is connected to the input of the analyzer (thus the input signal of the analyzer coincides with the output signal of the amplifier-converter 2).

The amplifier-converter 2 is configured to isolate the variable component of the signal of photodiode 1, its band gain (for example, for the case of alternating combustion of gas and fuel oil in the range of 40 ... 160 Hz) and one-way restriction (in this case, its entire positive region), and shift of the potential level (in the positive region) of the output signal. As a result, the time-average value of the analyzer input signal is directly proportional to the average amplitude of the pulsations of the light flux arriving at photodiode 1, and the dependence of the analyzer input signal on the absolute value of the light flux to photodiode 1, determined, in particular, by the type of fuel burned, is excluded (in this the adaptability of the nature of the control device is manifested).

The normalization circuit contains an integrator 3 and an adjustable element connected to its output, configured to change its active resistance under the action of the output signal of the integrator 3 and connected to the input of the amplifier-converter 2 with the possibility of changing the input resistance of the latter. The integrating input of the integrator 3 is connected to the output of the amplifier-converter 2, and the reference input is connected to the output of the normal signal source (not shown in Fig. 1). It is advisable to use an element of the electric circuit of the control device as a source, the constant potential of which is taken to be zero (for example, the potential of the common bus of the power supply, the latter is not shown in Fig. 1). The specified adjustable element (in FIG. 1 is included in the amplifier-converter 2) in this case is made in the form of npn bipolar transistor, the emitter and collector of which is connected to the input terminals of the amplifier-converter 2 (respectively, and the terminals of the photodiode 1), and the base is connected with the output of the integrator 3 normalization circuit. The specified adjustable element can also be made in the form of a field-effect transistor connected by a source and drain with the specified output and input, and a gate - with the output of the integrator 3.

The normalization circuit is designed to eliminate the deviations of the time-average value of the input signal of the analyzer from the normal signal, and in this case, to change the input resistance of the amplifier-converter 2 and, accordingly, the load of the photodiode 1 so that the sign of the indicated change is opposite to the sign of the deviation of the input the analyzer signal from the normal signal while maintaining a positive correlation of changes in the light flux to photodiode 1 and the signal of the latter. By connecting the base of the indicated bipolar transistor with the output of the integrator 3 in an appropriate manner (for example, through series-connected resistors, each of which is shunted by a diode, to obtain a piecewise linear change in the voltage at the base), it is possible to perform the time constant of the aperiodic process of eliminating deviations and approaching the normal signal, little dependent on the magnitude of the light flux to the photodiode 1.

The analyzer includes the first integrator 4, the second integrator 5 and the comparator 6 connected in series. Each of these elements (in this case) is based on an operational amplifier (op amp), the non-inverting input of which is connected to the reference input of the element. The output of the amplifier-converter 2 is connected to the integrating input of the first integrator 4, corresponding to the inverting input of the op-amp of the latter. The output of the first integrator 4 is connected to the integrating input of the second integrator 5, corresponding to the inverting input of its op-amp. The output of the second integrator 5 is connected to the inverting input of the op-amp of the comparator 6. The reference input of the first integrator 4 is connected to the output of the comparator 6 with the possibility of generating a reference signal equal to part of the output signal of the comparator 6. The reference input of the second integrator 5 is connected to the output of the normal signal source. The reference input of the comparator 6 is connected to its output.

The signal at the reference input of the first integrator 4 determines the size of the change in pulsations of the light flux incident on the photodiode 1, after which the device starts fixing this event, generating a signal for the security system. The first integrator 4 is designed to quickly isolate and record the fact of a significant change in the magnitude of the light flux to the photodiode 1. The second integrator 5 is designed to fix the fact that the duration of the specified change exceeds the standard period, which corresponds (according to safety rules) to the fact that the torch flame disappears (in particular , for energy steam generators, this period is 2 seconds). The indicated fixation must occur before the adaptation of the analyzer input signal to a new level of luminous flux is completed. For this, the integration time of the first analyzer integrator 4 is less than that of the second analyzer integrator 5, and the time constant of the process of approximating the analyzer’s average input signal to the normal signal is longer than the integration time of the second integrator 5 (in other words, the integration time is less than time constant). The output signal of the comparator 6 is designed to control information and executive devices of the security system (not shown in the drawings).

The technical means required to implement the features of the invention (both electrical elements of classical electronics and microelectronics microcircuits) are known from the prior art (see, for example, Agakhanyan TM Integrated microcircuits: Textbook for universities. - M .: Energoatomizdat, 1984. - 464 p.: Section 3.5.1, 5.2, 9.2; Digital and analog integrated circuits: Reference book / Under the editorship of S.V. Yakubovsky. - M .: Radio and communications, 1990. - 496 p.: Section 5.2 , 5.3).

During operation of the steam generator, the burner flame control device operates as follows. During normal operation of a single burner, to which photodiode 1 is directed, the time-average input signal of the analyzer is equal to (due to the adaptation of the device to the state of the furnace in the case of a sufficiently long continuous glow of the flame) the normal signal (in this case, zero potential). The area of the positive area on the plot of this signal is equal to the area of the negative area (see figure 2). The output signal of the integrator 3 of the normalization circuit corresponds to the input resistance of the amplifier-converter 2 and the load resistance of the photodiode 1 required for this state, and the input current of the integrator 3 is zero. By inverting the input signals in the analyzer, the output signal of the integrator 4 coincides with the upper level, the output signal of the integrator 5 coincides with the lower level, and the output signal of the comparator 6 coincides with the upper level (see Fig. 4). For a safety system, such an analyzer output state corresponds to the fact of the presence of a flame of a controlled burner.

With the disappearance (extinction) of the flame of the specified burner, the magnitude of the light flux entering the photodiode 1, as well as the ripple of the light flux, jumps, respectively, the ripple of the signal of the photodiode 1 decreases. Due to the fixed shift of the output signal of the amplifier-converter 2, the area of the positive region by the diagram of the input signal of the analyzer becomes larger than the area of the negative region (see the first part of figure 2), and the average time value of this signal grows. The output signal of the integrator 3 of the normalization circuit is reduced (due to inversion of the input signal and the charge of the capacitance of this integrator), with approaching the level corresponding to the new value of the light flux (i.e., without glow of the flame of the controlled burner). Reducing the voltage on a bipolar transistor reduces its base current and increases its active resistance. This, in turn, increases the input resistance of the amplifier-converter 2 and, accordingly, the load of the photodiode 1 (due to the weakening of their shunting), which leads to an increase in the ripple of the signal of the photodiode 1. Due to the specified fixed shift, a corresponding increase in the ripple of the output signal of the amplifier-converter 2 entails a decrease in the time-average value of the input signal of the analyzer (see the second part of FIG. 2) and the gradual elimination of its deviation from the normal signal that occurred when the torch disappears. The time constant of this aperiodic (see Fig. 3) transient process (for example, from a range of 10 ... 20 s) does not depend on the luminous flux to photodiode 1 (which depends mainly on the type of boiler and type of fuel burned), but is determined only the parameters of the normalization scheme (this also shows the adaptability of the nature of the control device).

After the input signal of the first integrator 4 of the reference signal (threshold), the output signal of the integrator 4 quickly drops to the lower level (see figure 4). After the input signal of the second integrator 5 falls below the level of the normal signal, the output signal of the integrator 5 goes to the upper level (in this case, within 2 s). After exceeding the input signal of the comparator 6 of its reference signal, the output signal of the comparator 6 goes to the lower level. For a safety system, such an analyzer output state corresponds to the fact that there is no flame of the controlled burner.

In a situation of the appearance of a flame, the device works similarly, but with a change in the signs of signal deviations to the opposite.

In this case, the disappearance or appearance of the torch of the burner is detected by analyzing changes in the output signal of the amplifier-converter 2 in the process of adapting the device to current conditions (in particular, the radiation parameters of the furnace).

In cases where the deviation of the input signal of the analyzer is associated not with the loss of the flame, but with resource changes and operational deviations, and, in the general case, does not exceed the response threshold of its first integrator 4, only the device adapts (due to the normalization circuit) to changing operating conditions. Due to adaptation (without manual adjustments and switching), compensation is made not only for the aging of the elements of the device and for reducing the transparency of the optical path, but also for other destabilizing factors affecting the average value of the analyzer input signal: ambient temperature, power instability, etc.

Due to the above adaptation and compensation, it is possible to reduce the optimal threshold level of the monitoring device without increasing the likelihood of false signals for the security system.

According to the operating conditions of energy and industrial boilers, the flame control device is usually performed as a part of two units connected by a communication line. The first block (sensor) includes a photodiode 1 and an amplifier-converter 2, and the second block (secondary device) includes analyzer elements. The noise immunity of the flame control device to interference that varies according to the law of alternating current, which can occur in a fairly long (in general) connecting line, is due to the fact that the alternating signal does not pass to the outputs of the integrators 3, 4 and 5 due to the mutual (average ) the cancellation of the positive and negative areas on the plot of such a signal (in contrast to the fact that signal changes that carry useful information are accumulated by integrators).

For the operation of the control device does not require any information additional to that which carries the signal of the photodiode 1, which allows to simplify the design of the device.

Claims (2)

1. Adaptive device for controlling the flame of the burner, containing a series-connected photodiode, an amplifier-converter of the output signal of the photodiode and an analyzer of the output signal of the amplifier-converter, characterized in that it is further provided with a normalization circuit for the input signal of the analyzer, the normalization circuit contains an integrator, the integrating input of which is connected to the output amplifier-converter, and the reference input with the output of the normal signal source, and connected to the output of this integrator are adjustable an element made with the possibility of changing its active resistance under the action of the output signal of the specified integrator and connected to the input of the amplifier-converter with the possibility of changing its input resistance, while the amplifier-converter is configured to isolate the variable component of the output signal of the photodiode, its band gain and one-way limitation and a fixed shift of the potential level of the input signal of the analyzer, and the normalization circuit is configured to the deviation of the average time deviation of the analyzer input signal from the normal signal, the analyzer is made in the form of series-connected first and second integrators and a comparator, the reference input of the comparator is connected to its output, the reference input of the second analyzer integrator is connected to the output of the normal signal source, and the reference input of the first analyzer integrator - with the output of the comparator with the possibility of generating a reference signal equal to a part of the output signal of the comparator, while the integration time of the first th integrator analyzer configured smaller than that of the second integrator analyzer, and last integration time less than the time constant approximation process medium on an input signal analyzer to normal time signal. 2. The adaptive burner flame control device according to claim 1, characterized in that the adjustable element with the possibility of changing its active resistance is made in the form of an npn bipolar transistor, the emitter and collector of which are connected to the input terminals of the amplifier-converter, and the base is connected to the output of the circuit integrator normalization.

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