SU1681180A1 - Method and device for controlling massive release of pollutants from thermal utility units - Google Patents

Abstract

The invention relates to instrumentation, in particular, to devices for analyzing industrial emissions into the atmosphere, and can be used to control the mass emission of pollutants in heat and power, oil refining, pulp and paper, and other industries that use processes in process plants. The aim of the invention is to improve accuracy and reduce labor intensity. The invention provides a determination of the mass emission of a substance in relation to its concentration in the exhaust gases to the concentration of sulfur dioxide and the adjustment of this ratio in terms of the sulfur content in the fuel combusted in the heat and power unit per unit of time. The concentration is determined using gas analyzers, and the amount of burnt sulfur is determined by the sulfur content of the fuel and its consumption. 2 sec. f-ly, 1 ill. cl

Description

The invention relates to instrumentation, in particular to the means of analyzing industrial emissions into the atmosphere, and can be applied in heat and power engineering and other industries that use processes for burning fuel (refinery, pulp and paper, etc.) in process plants to control mass emissions substances in the atmosphere.

The purpose of the invention is to increase accuracy and reduce labor intensity.

The drawing shows a block diagram of a system for controlling mass emissions of pollutants by heat and power units.

The system consists of a nitrogen monoxide 1 gas analyzer, a sulfur dioxide 2 gas analyzer, a carbon monoxide gas analyzer 3, a fuel consumption measurement unit 4, a sulfur content setting unit 5 in the fuel unit

6 divisions installed in the channel for determining the mass emission of nitric oxide, input

7 of which is connected to the output of the gas analyzer 1 nitric oxide, and the input 8 of the separator is connected to the output of the gas analyzer 2 of sulfur dioxide, dividing unit 9, the input 10 of which is divisible is connected to the output of the gas analyzer 3 of carbon monoxide, and the output 11 of the divider sulfur dioxide 2. The multiplication unit 12 installed in the mass definition channel

one

about

sulfur dioxide emission, the inputs are connected with the fuel consumption measurement unit 4 and the sulfur content setting unit 5 of the fuel. The inputs of multiplication unit 13 installed in the mass determination of the emission of nitric oxide are connected to the outputs of division 6 and multiplication unit 12, the inputs of multiplication unit 14 installed in the carbon monoxide emission detection channel are connected to the outputs of division 9 and multiplication unit 12.

Signals proportional to the mass emissions of nitric oxide, sulfur dioxide and carbon monoxide are removed from the outputs of multiples 13-15, respectively.

The system works as follows. Before starting the measurements in block 5, the setting of the sulfur content in the fuel is determined by the amount corresponding to the sulfur content of the fuel according to the passport (certificate) of the fuel used in the heat and power unit during the emission monitoring period. The setting of the sulfur values is made using a potentiometer. From the moment the control starts, the analog signal from the fuel consumption measurement unit 4 arrives at the input of multiplication unit 12 installed in the channel for determining the sulfur dioxide emission in May, the second input of which receives a signal proportional to the sulfur content of the unit 5. In multiplication unit 12, the analogs multiply signals arriving at its inputs. In this case, in block 12, a signal appears that is proportional to the amount of sulfur in the fuel burned in the heat and power unit per unit of time. Since the mass emission of sulfur dioxide is unambiguously related to the consumption of sulfur per unit of time through the molecular weights of sulfur dioxide and sulfur (2: 1) in multiplication unit 12, production of получ is doubled, and a signal proportional to mass emission occurs at the output of multiplication unit 12 sulfur dioxide. At the same time, a signal from the nitrogen oxide analyzer is fed to the input 7 of the dividend dividing unit 6 installed in the mass determination of nitric oxide, and a signal from the sulfur dioxide 2 gas analyzer to the input 8 of the divider of the 6 dividing unit 6 concentrations of nitric oxide and sulfur dioxide, which is fed to one of the inputs of multiplication unit 13 installed in the channel for determining the mass emission of nitric oxide B

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multiplication unit 13 multiplies the signal from division unit 6 by a signal proportional to the mass emission of sulfur dioxide from the multiplication unit 5 to the second input of multiplication unit 13.

Thus, the signal at the output of multiplication unit 13 is directly proportional to the mass emission of sulfur dioxide and inversely proportional to the concentration of sulfur dioxide in the exhaust gases. Considering that the volume of waste gases is associated with the mass emission of sulfur dioxide and its concentration by the ratio

15

MSo2 V Cso2,

where Mso, is the mass emission of sulfur dioxide per unit of time;

™ v is the gas flow rate through the flue per unit of time;

Cso ;, is the concentration of sulfur dioxide in the exhaust gases,

the output signal of the multiplication unit 12 is directly proportional to the gas flow through the duct.

On the other hand, the signal at the output of the multiplication unit 13 is directly proportional to the concentration of nitric oxide in the exhaust gases. Thus, the signal at the output of multiplication unit 13, proportional to the flow of gases through the duct per unit of time and the concentration of nitric oxide in the waste gases, is directly proportional to the mass emission of nitric oxide from the duct.

Similarly, the channel for determining the mass emission of carbon monoxide works. From the output of dividing unit 9, a signal is removed that is proportional to the ratio of carbon monoxide and sulfur dioxide concentrations. This signal is corrected in multiplication unit 14 in accordance with the value of the mass emission of sulfur dioxide supplied as an analog signal from reproduction unit 12. In this case, the output of the multiplication unit 14 produces a signal proportional to the mass emission of carbon monoxide.

25

thirty

35

AO

Thus, the signals at the outputs of the multiplication units 13–15 are proportional to the mass emissions of the emitted pollutants: nitrogen oxides, sulfur dioxide and carbon monoxide, respectively. In this case, the mass emission of sulfur dioxide is determined by the fuel consumption and its sulfur content, and the mass emissions of nitric oxide and carbon monoxide are determined by the concentration of the corresponding pollutant, and

sulfur dioxide concentrations and massive sulfur dioxide emissions.

Claims (2)

1. A method of controlling the mass emission of pollutants by heat and power units by measuring the concentrations of nitric oxide, carbon monoxide and sulfur dioxide in exhaust gases, characterized in that, in order to increase accuracy and reduce labor intensity, the content of sulfur in the fuel burned is additionally measured in the heat and power unit per unit of time, the concentration of nitrogen oxide and carbon monoxide is determined by the concentration of sulfur dioxide and the ratio is proportional to the sulfur content in the fuel; in the heat and power unit per unit of time. 2. A system for controlling the mass emission of pollutants by thermal power units, containing gas analyzers for determining the concentrations of nitric oxide, carbon monoxide and sulfur dioxide, and the first, second and third multiplication units installed in the channels for determining mass emissions of nitrogen oxide, carbon monoxide and sulfur dioxide, respectively, characterized in that, in order to increase accuracy and reduce labor intensity, a fuel consumption measurement unit is added to its composition, 5 unit of sulfur content in the fuel, the first and second dividers installed in the channels for determining mass emissions of nitric oxide and carbon monoxide, respectively, the outputs of the flow measurement unit 0 fuel and sulfur detector in fuel are connected to the first and second inputs of the third multiplication unit, the first input of the first divider is connected to the gas analyzer output for the nitrogen oxide, the output of the analyzer for determining the concentration of sulfur dioxide is connected to the second input of the first divider and the first input of the second splitter, the first input is connected to the output 0, a gas analyzer for determining the concentration of carbon monoxide, the output of the first divider is connected to the first input of the first multiplication unit, the output of the second divider is connected to the first input of the second. 5 of the multiplication unit, the second input of which is connected to the first output of the third multiplication unit, the second output of which is connected to the second input of the first multiplication unit.