SU937870A1 - Method of determining heat release in steam generator fire box - Google Patents

Description

(3) METHOD FOR DETERMINING A WARM ES 1DELECTION BY A FLOWING CHAMBER OF A STEAM GENERATOR

one

The invention relates to a power system, and in particular to methods for measuring thermal values.

Methods are known for determining heat generation in the combustion chamber of a steam generator by measuring characterizing its parameters and calculating the heat release value from measured signals.

In the method, the parameters characterizing heat generation in the furnace chamber use the medium temperature at the intermediate point, the flame emission or the flue gas temperature CO.15

The disadvantage of this method is the dependence of these parameters on the heat exchange process occurring in the combustion chamber. In addition, the method allows only 20 local heat generation to be determined. These disadvantages reduce the accuracy of determining the amount of heat generation in the combustion chamber of the steam generator.

The purpose of the invention is to improve the accuracy of measurement of heat generation in the combustion chamber.

This goal is achieved by using the flow rate of air supplied to the combustion chamber and the flow rate of flue gases removed from it as parameters characterizing the heat generation in the combustion chamber of the steam generator,

In addition, the flow rate and humidity of the supplied fuel are additionally used as parameters characterizing heat generation in the furnace of the steam generator.

In addition, the signals for fuel and air consumption and the signal for the humidity of the fuel are dynamically transformed before calculating the heat spirits in the combustion chamber.

The drawing shows the circuit implementation of the method.

The flow rate of air supplied to the combustion chamber 1 of the steam generator is measured by sensor 2, the fuel consumption by sensor 3 and the moisture of fuel by sensor 4. The consumption of flue gases generated by the combustion of fuel is measured by sensors 5 - The output signals of sensors in certain combinations served on computing device 6, which is a complex of algebraic blocks. The output of the computing device enters the information and control circuitry. To improve the accuracy of determining heat generation in transient modes, signals on the total air and fuel consumption and the signal on the fuel moisture are fed through dynamic links 7–9, respectively. Dynamically, these links should be equivalent to the combustion chamber through the channels. Total air consumption - flue gas consumption Fuel consumption - flue gas consumption and Fuel Humidity - flue gas consumption, respectively. The method is carried out as follows. Heat dissipation in the combustion chamber is determined by the formula VK. () where B is the weight consumption of fuel supplied to the steam generator, measured by sensor 3; B-- the proportion of fuel with calorific value; tcG B-in (2) where Q.P is the average lower specific heat of combustion of the working fuel. The amount of air required to burn the incoming fuel is determined by the formula for R ;, QL ± 6w о о оа innn where a is a constant coefficient depending on only the type of fuel burned (for example, for coal from outlets to Donetsk Litracy does not change and it is equal to 1.1); W is the working humidity of the fuel, in fact, the amount of air supplied to the steam generator, measured by sensor 2, is always slightly higher, i.e. V ctVo where o (- coefficient of excess air -). The volume of flue gases formed in the combustion process and measured by sensor 3 with regard to temperature increase and volume expansion is determined by the formula VAV, B (A + 1, (Qj + 6wP) + B12, A, 10, where L is a constant factor , depending on the type of fuel burned. Using the above formulas, the parameters can be determined with an accuracy of 1%. Solving jointly Eqs. (2) - (5), we get - (VAMH.OIbVoJ O -BfeWPCA g.OfeT) (b) vn.fd Provided that / 1, and not taking into account the weight consumption of fuel and its moisture content, we obtain the formula а .. „- ---- If“ s, which for Ekibastuz coals has an accuracy of about 20. When measuring the weight consumption of fuel, considering the fuel moisture constant, we get the formula Q yekH: Uoi6v $: ig zBKk ± 2., g6zbgj .. Where K 6wtp; WJL is the average moisture content of the working fuel that has accuracy for Ekibastuz coal less than measuring the moisture content of the fuel sensor k Q is determined by the formula (6), which has an accuracy of about -2% for Eq bastuz coals. Considering the errors in measuring the flue gas flow rates by sensor 5 and air sensor 2, fuel consumption by sensor 3 and its humidity by sensor k formula (6) gives an accuracy of up to 6-8%. The proposed method can significantly improve the accuracy of measuring heat generation in the combustion chamber of a steam generator. In addition, the use of the proposed method makes it possible to determine a number of physicotechnical parameters of the combustion process, which are determined indirectly or are not determined due to the impossibility of determining heat generation in the furnace

steam generator chamber. These parameters include: the average lower calorific value of the fuel supplied to the steam generator, the average ash (fuel, stoichiometric air flow, oxidizer excess ratio, efficiency, etc.

Claims (3)

1. A method for determining heat generation in a furnace of a steam generator By measuring characteristic parameters followed by calculating the amount of heat generation, characterized in that, in order to increase accuracy, the flow rate is measured as characteristic parameters air supplied to the combustion chamber, and the flow of flue gases removed from it. 2. Method pop. 1, differing from the fact that the flow rate and moisture content of the fuel supplied to the combustion chamber are measured as additional characteristic parameters. 3. Method according to PP.1 and 2, which means that the measured characteristic parameters for fuel and air consumption and the moisture content of the fuel are dynamically transformed before calculating the amount of heat release. Sources of information taken into account in the examination 1. USSR author's certificate No. 567027, cl. F 23 N 1/00, 1975. U777777L T9pli9v 7u7 / 77/7 7777/7 7 7l7U77 777 U L UU Gwtn1nv lvmvra