DD230646A3 - METHOD FOR EVALUATING THE COMBUSTION CONDITIONS IN GAS FIRES - Google Patents

Abstract

The invention relates to an evaluation method for the combustion processes in gas firing, by which a definition of operating parameters is carried out in order to keep constant the heat supply of the furnace regardless of fluctuations in the gas supply in terms of quality, quantity or composition. It is the object of the invention to guarantee the exact compliance with the required operating parameters using minimum amounts of fuel. According to the invention, this is achieved by catalytically oxidizing a partial gas stream parallel to the main furnace in a gas-potentiometric titration measuring cell and, in evaluating the equilibrium cell voltage resulting from a solid-electrolyte sensor, controlling the gas and / or air flows to maintain stoichiometric combustion. The invention is applicable to any type of gas firing. figure

Description

Field of application of the invention

The invention relates to a method for assessing the combustion conditions in gas firing, by which a determination of operating parameters is made.

In this case, the fuel gas-air ratio is set in accordance with the heat to be released by the combustion according to the technical requirements by means of control devices.

Characteristic of the known technical solutions

In order to set optimum operating parameters and to monitor the combustion conditions in industrial gas firing, analyzes of the fuel composition and the exhaust gas composition, in this case primarily the oxygen content, currently form the basis. These analyzes are carried out by means of very different methods and measuring devices and usually used in such a way that after completion of combustion from the measured values obtained at the exhaust gas with respect to the fuel analysis and the set flow rates corresponding conclusions are drawn. Also for the control of burners measured values of the exhaust gas composition are increasingly used (DD-PS 133996) measurements in the exhaust gas as a basis of the known evaluation and monitoring methods are very sensitive to false air intrusions. Since they are performed only after completion of combustion, they are only partially suitable to exert an immediate effect on the combustion conditions. Fluctuations or disturbances in the flow rates of the fuel gas or the combustion air and short-term changes in the fuel gas composition are difficult to detect with certainty.

Other methods for assessing the combustion conditions in gas firing are based on the assessment of a diverted from the main gas flow to the burner partial gas flow.

Thus, a method is known in which such a partial gas stream is burned in conjunction with a partial flow of the supplied combustion air in a caloriemeterähnlichen sample oven. After this combustion process and the temperatures achieved here, the fuel gas and combustion air supply to the main burner is regulated. (US-PS4118172) The operation of such a caloriemeterähnlichen sample furnace for a partial gas flow is firstly materially very expensive. Secondly, such a sample furnace is burdened with specific disadvantages for the sample combustion, thirdly, there is still a significant inertia of the system, so that short-term fluctuations in quantity, quality or composition of the fuel gas can be compensated only very slowly in the main firing.

Object of the invention

The object of the invention is to provide a method of evaluation of the combustion conditions in gas firing, in order to always allow, in the short term, the conditions required for a stoichiometric combustion, irrespective of the quantity, quality and composition of the fuel gas, thus ensuring exact compliance with the required operating parameters

given the necessary fuel gas and air demand of the gas firing, so as to achieve the required heat output using the lowest fuel quantities and thus to achieve fuel savings.

Explanation of the essence of the invention

The invention has for its object to provide a method for evaluating the combustion conditions in gas firing, which makes it possible to quickly and continuously to investigate the fuel gas flow supplied to a burner or a burner group with respect to the required air for its complete combustion, the stoichiometric combustion conditions also always to ensure short-term fluctuations in the gas flow rates or the fuel gas quality during operation of the furnace.

In this case, the technical complexity of the measuring and control device is to keep low, to achieve a high level of technical safety and rapid availability of information, so that in case of changes or disturbances of the operating conditions their effects on the heat release in the gas firing need not be awaited. According to the invention, this object is achieved in that the partial flow of the fuel gas is fed continuously and defined a gaspotentiometric Titrationsmeßzelle for flameless catalytic oxidation by metered addition of oxygen or air. The electrical signal resulting from the oxidation on the solid electrolyte sensor of the titration cell is then evaluated to determine the fuel and / or air requirement required for stoichiometric combustion and the required input heat flow, and the result is then used to control the operating parameters in the main gas and / or or main air flow of the burner fed back.

According to the invention, it is also possible to proceed in such a way that the continuous partial gas stream branched off from the main gas stream is catalytically oxidized catalytically to the equivalence point in the gaspotentiometric titration measuring cell and the electrical signal resulting from the solid electrolyte sensor is determined to determine the fuel / air ratio. Ratio is used.

A further embodiment of the method according to the invention is that the diverted, defined and continuous partial gas stream is oxidized catalytically flameless with a constant defined oxygen or air flow in the gas-potentiometric titration. From the deviation of the electrical signal generated at the solid electrolyte sensor as the actual value of the value determined for the equivalence point as the desired value, the fuel gas and / or air quantity required for a stoichiometric combustion at the burner is determined and / or air is supplied to the nominal value in the main gas and / or or main air flow fed back.

Furthermore, according to the inventive solution, the branched and defined, continuous partial gas stream can be catalytically oxidized flamelessly with a constant oxygen or air stream in the gas-potentiometric titration measuring cell. The electric signal generated at the solid electrolyte sensor is evaluated as a measure of the calorific value of the fuel gas. Subsequently, this value is fed back for controlling or controlling the fuel gas supply to the burner in the main gas stream.

The inventive solution further includes that the main gas flow and the main air flow to the burner ever removed a directly proportional Teiistrom and the gaspotentiometric Titrationsmeßzelle is supplied. The caused by fluctuations in the main gas and / or main air flow deviation in the electrical signal resulting from the solid electrolyte sensor as the actual value of the signal of the equivalence point as the setpoint for pre-feeding the supplied main gas and / or main air flow to the burner to the stoichiometrically necessary fuel gas and air quantities in the main gas flow of the fuel gas and / or the main air flow fed back.

embodiment

The invention will be explained in more detail with reference to an embodiment.

The accompanying drawing shows the basic structure of a device for carrying out the evaluation method according to the invention.

A burner 1 is a main gas stream 2 of a fuel gas and a main air stream 3 is supplied to carry out a combustion. In the main gas stream 2, a sampling device 4 is provided, through which the main gas stream 2, a partial gas stream 5 is removed. The partial gas stream 5 is supplied after measurement in a Mengenmeßstelle 6 a gaspotentiometric Titrationsmeßzelle 7, which is preferably designed as a flow cell.

The titration measuring cell 7 is further supplied with an air flow 9 by means of a feed pump 8, the measured values of which (eg the flow rate) are measured in a measuring point 10.

The gaspotentiometric titration measuring cell 7 consists essentially of a mixing chamber, a catalyst and an oxide ion-conducting solid electrolyte sensor. For better readability of the measured values, it is advantageous to operate the gas-potentiometric titration measuring cell 7 at a constant temperature of 813 ° C.

The implementation of the evaluation method according to the invention of the combustion conditions in gas furnaces is the following:

The gaspotentiometric titration measuring cell 7 is supplied with a measured by the Mengenmeßstelle 6 partial gas stream 5 of the main gas stream 2. As a result of the passage of this partial gas stream 5 together with the air stream 9 is formed in the solid electrolyte sensor of the gaspotentiometric Titrationsmeßzelle 7 a respective prevailing oxygen partial pressure corresponding electrochemical potential, which is measured and detected in comparison to a reference electrode operated with air of the same kind as equilibrium cell voltage. This results in a titration curve to be assigned to the respective fuel gas. The inflection point of this titration curve from excess fuel to excess air characterizes the equivalence point for this fuel gas, thus giving the equilibrium cell voltage 11 which adjusts itself to the stoichiometric air requirement. The fuel gas / air ratio to be determined in this way for this fuel gas to be evaluated is then transferred to the controller 12 the main gas stream 2 and fed back to the control 13 of the main air stream 3. This ensures the conditions for a stoichiometric combustion at the burner 1. Of course, it is equally possible to carry out the regulations 12 and 13 such that, on the basis of the titration results, an operation of the burner 1 with a certain excess of air can also be carried out. For clarity, the representation of the corresponding control circuits in the figure was omitted.

If there is a fluctuation in the quantity or the composition in the main gas flow 2 of the fuel gas, the value of the equilibrium cell voltage 1T in the titration measuring cell 7 also changes as a result if it continues to be supplied to the constant air flow 9 corresponding to the equivalence point.

The currently required for the stoichiometric operation of the burner 1 size of the air stream 3 can be determined from the deviation from the equivalence point corresponding to the titration curve and adjusted by the controller 13, or their size can be determined that a change in the air flow 9 to Titrationsmeßzelle 7 so long takes place until the value of the equilibrium cell voltage 11 for the equivalence point is reached again. On the basis of the division ratio of the main gas stream 2 and the partial gas stream 5, which is established for the sampling device 4, the corresponding correction can then be made by the controls 12 or 13 to the main gas stream 2 or the main air stream 3, or to both streams. If z. B. for a given main gas stream 2 in the titration 7 at an original stoichiometric air supply equilibrium cell voltage 11 e _{eq s} , a _ch , so this means at a constant amount of Gäszüführung too low oxygen or air supply. A value U _eqstöch . indicates oxygen or air excess. Of course, both deviations can be caused by the fact that the fuel gas composition has changed with constant supply and thus a different oxygen or air supply is required. In this case, the deviation from the size of the equilibrium cell voltage 1T for the stoichiometric combustion is at the same time the measure for the change in the calorific value. A corresponding evaluation follows also for the case that both a partial gas flow 5 and a partial flow of the main air stream 3 are removed by sampling the supply to the burner 1 and the titration 7 are supplied.

The particular effect of the method according to the invention for assessing the combustion conditions in gas firing systems is above all that it is possible to determine the corresponding characteristic values required for stoichiometric combustion, such as the fuel / air ratio and the calorific value determination, in parallel to the main firing and to immediately feed their results into the control of combustion without first having to wait for measurements from the burnout result of the gas firing. This makes it possible to respond immediately to fluctuations in the gas flow rate or in the fuel gas quality or composition by appropriate regulations in order to realize an always consistent heat supply to the burner 1 can.

Claims (5)

Invention claim: 1. A method for assessing the combustion conditions in gas firing, in which a partial gas flow is branched off from the main gas flow of the fuel gas for a burner or a burner group, characterized in that - The partial gas stream (5) of the fuel gas continuously and defines a gaspotentiometric Titrationsmeßzelle (7) for flameless catalytic oxidation supplied by metered addition of oxygen or air, - Evaluated by the solid electrolyte sensor resulting electrical signal to determine the required for a stoichiometric combustion and the required input heat flow fuel and / or air requirements and - The result is then fed back to the control or regulation of the operating parameters in the main gas and / or main air flow (2, 3) of the burner "(1). 2. The method according to item 1, characterized in that the diverted and defined, continuous partial gas stream (5) in the gaspotentiometric Titrationsmeßzelle (7) is catalytically oxidized by metering in oxygen or air to the equivalence point flammenlos and the solid electrolyte sensor resulting electrical signal to determine the fuel-air ratio is used. 3. The method according to item 1 or 2, characterized in that - The branched off and defined, continuous partial gas stream (5) with a constant, defined oxygen or air stream (9) in the gaspotentiometric Titrationsmeßzelle (7) catalytically flamelessly oxidized, - determined from the deviation of the electrical signal resulting from the solid electrolyte sensor as the actual value of the value determined for the equivalence point as desired value for a stoichiometric combustion at the burner (1) required fuel gas and / or air quantity and - Is fed back to bring the actual value to the setpoint in the main gas stream (2) and / or the main air stream (3). 4. The method according to item 1, characterized in that the branched off and defined, continuous partial gas stream (5) with a constant and defined oxygen or air flow (9) in the gaspotentiometric Titrationsmeßzelle (7) catalytically oxidized flameless and the solid electrolyte sensor resulting electrical signal evaluated as a measure of the calorific value of the fuel gas and then fed back to the control or control of the fuel gas supply to the burner (1) in the main gas stream (2). 5. The method according to item 1, characterized in that the main gas stream (2) of the fuel gas, a directly proportional partial gas stream (5) and the main air stream (3) removed a directly proportional partial air flow and the gaspotentiometric Titrationsmeßzelle (7) are fed to the flameless catalytic oxidation, wherein the deviation caused by fluctuations in the main gas flow (2) and / or main air flow (3) in the electrical signal generated at the solid electrolyte sensor as the actual value of the signal of the equivalence point as a setpoint for the supply of the supplied main gas and / or main air stream (2; Burner (1) is fed back to the stoichiometrically necessary fuel gas and air quantities in the main gas stream (2) and / or the main air stream (3). For this 1 page drawing