SU998908A1 - Gas analyzing system - Google Patents

Description

The invention relates to an analytical technique and can be used in automated gas analysis systems, in particular, to control technological processes for smelting iron and steel at ferrous metallurgy enterprises.

A gas analysis system is known, containing samplers, 4 & sample preparation, primary transducer and recording devices 1 ;.

The disadvantage of this system is the considerable size, which is mainly caused by transportation.

A gas analyzing system is also known, comprising sample collectors connected to the sample transportation line, a sample preparation unit and a primary measuring transducer 23.

However, such a system is also characterized by a significant dingyly error due to the large length of the transportation lines of the analyzed gas samples.

The closest to the technical essence of the invention is a gas analytical system containing

the primary transducer, whose input through the sample preparation device, the trajectory line and the sampling device t is connected to the input of the input module. my mixture, the decoction unit, and the summation unit, installed at the outlet of the gas analytical system s |}. Disadvantages of the known system

10 are design complexity and low accuracy.

The purpose of the invention is to improve accuracy by taking into account the retardation time.

15

This goal is achieved by the fact that the system is equipped with a unit for calculating the derived signal and an input line for the transport delay value connected to one of the

The 20 inputs of the multiplication unit, another input of which is connected to the output of the derivative calculating unit, when This output of the primary measuring converter is connected to the input of the derived signal and the first input of the summation unit, to the second input of which the multiplication unit is connected.

The drawing shows a block diagram of a gas analytical system.

The system consists of an input line 1 for the analyzed mixture, a sampling device 2, a conveyor line 3 and a sample preparation device 4, a primary measuring converter 5, a derivative calculation unit 6, a summation unit 7, a multiplication 8, a gas analytic output line 9 and 10 system.

When describing the operation of the system, the following notation is used:

the value of the output signal of the primary gauge- and of the transducer and its derivative at time t. ;

the value of the transport lag; 20

 ti v (.,) signals at the output of the primary measuring transducer 5, equivalent to concentrations 25

.c ,,) ..- chh

the test subject at the sampling point in

moments (t. -C) h t; COOT-30

veteran

The physical system works at once.

The T-j value is determined in advance. transport lag (empirically, experimentally or in the process of analysis, for example, by forming a flow mark at the sampling point with determining the time it passes through the ducts of the system).

The analyzed mixture from the sampling site — input I through sampling device 2 and transport line 3 enters sample preparation device 4, where the sample is subjected to appropriate processing, i.e. cleaning, maintaining the set temperature, humidity pressure, etc., after which the sample of the analyzed mixture, normalized to the specified parameters, with an interval T from the moment it enters input 1 is fed to the input of the primary measuring converter 5. At the output of the primary measuring converter 5 in During the analysis process, a 3C (rt4-C) signal is generated (equivalent to the concentration of the .t-) component in the analyte carried in the den (ti-f-) at input 1 of the gas analysis system. The signal V4; i9C (. ,,) from the output of the primary measuring transducer 5 is fed to the input of the summation unit 7 and the production calculation unit 6 -. signal.

The value V of the derived signal from the output of block b is fed to one input of block 8 multiplication, the second input of which is supplied with the value T} of the transport lag of the system. From the output of the multiplication unit 8, a signal proportional to the product vt is fed to the second input of the summation unit 7, the output of which forms the final analysis result taking into account the transport delay of the gas analysis system

-.

Thus, knowing the value of the transport lag of the system and assuming that the calculated value V of the derived signal does not change significantly in the interval

,,

By performing additional complex measuring and converting operations with the input signal of the primary measuring converter, the dynamic analysis error is significantly reduced in this gas analysis system.

The annual economic effect from the implementation of the invention only in the process control system of the converter shop will be about 80 thousand rubles.

Claims (3)

1. USSR Author's Certificate No. 757952, cl. G 01 N 25/26, 1978. 2. Golovchenko P.F. and others. Automated system ASGA-N and use of the converter room 5998908 fusible. Sat scientific papers VNIAP 3. USSR author's certificate Elements, devices, and gas systems of the application, No. 3221425 / 23-26, analysis, Kiev, 1979, p. 8-12s. cl. G 01 N 7/00, 1980.