SU981761A1 - Air excess factor determining method - Google Patents

Description

(, 54) METHOD FOR DETERMINING THE EXHAUST COEFFICIENT

The invention relates to the use of gaseous and liquid fuels in industrial heating devices and may find application in controlling the combustion of fuel in furnaces for heating a metal before it is rolled or forged.

An indirect method for determining the air excess factor is known, which involves taking a sample of flue gases and subsequent analysis of oxygen using an automatic magnetic gas analyzer 1. In the presence of oxygen in the combustion products, the flow rate of air used for burning is reduced. The principle of operation of a magnetic gas analyzer on O is based on the magnetic susceptibility of oxygen. In this case, the phenomenon of thermomagnetic convection of an oxygen-containing gas in a non-uniform magnetic field in the presence of a temperature gradient in the gas is used.

The disadvantage of this method is the large thermal inertia of the sensor and low sensitivity (not more than 8 mV /% O), and the dependence of its readings on the ambient temperature, gas flow

and its pressures. This does not allow for the required accuracy.

The closest to the invention is the Method of determining the air excess coefficient by measuring the temperature of combustion products and other parameters and further calculating the air excess coefficient using the formula 121.

ten

This method is characterized by low accuracy, due to the insufficient accuracy of measurement of the parameters included in the formula.

15

The aim of the invention is to improve the accuracy of determining the coefficient of excess air.

The goal is achieved by additionally measuring

20, the heat flow of the combustion products with the help of two sensors having different degrees of blackness of the receiving surfaces, and the value of the coefficient of excess air determine

25 according to the formula

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-Kat

thirty

Claims (1)

Claim A method for determining the coefficient of excess air by measuring the temperature of the combustion products, characterized in that, in order to improve the accuracy, they additionally measure the heat flow of the combustion products using two sensors having different degrees of blackness of the receiving surfaces, and the value of the coefficient of excess air is determined by the formula '· (D - K ₃ + K ₂ combustion products - cj, ₂ using two sensors having different degrees of blackness of the receiving surfaces and E ₂ , the coefficient of excess air is determined by the formula where (E <e ₂ ) bt ⁴ I-1-Ch2 d - Stefan-Boltzmann constant Κ _ή , K _? , K ₃ - constant coefficients, depending on. fuel: for gas K ^ = 0.25, K ₂ = 0.65; K ₃ = = 1.28-10 ^-3 , for fuel oil ^ = 0.27; K ₂ = 0.43; K ₃ = 1.12-10 ~ *. l · iZZZZZZZZl EZZZZZZZZ? Yo 8 not gao / <-ft ’4U 77/77777777 / 7777ZZ? where E ₃ / e ₂ - the degree of blackness of the receiving surfaces of the sensors; <^ and are the readings of heat flux sensors; 6 - Stefan Boltzmann constant; T is the average temperature of the combustion products; K _1G K ₂ , k ₃ - constant coefficients depending on the fuel: for gas K _d = 0.25 K ₂ = 0.65; K _e = 1.28 · 10 ^-3 ; for fuel oil K ₁ = 0.27; K _g = 0.43 ', K ₃ = 1.12-10 *.