SU1693322A1 - Device for automatic control of oxidation process in unit with fluidized layer - Google Patents

Abstract

The invention relates to automatic process control devices, occurring in a fluidized bed, in particular, the regulation of a predetermined ratio of oxidant-reagent and fluidization regime, and can be used in processes of fuel combustion and oxidation in a fluidized bed of catalyst. The purpose of the invention is to improve the quality of regulation. This is achieved by the fact that a device for automatically controlling the oxidation process in a fluidized bed installation, including analyzers 6 and 4 of hydrogen sulfide and sulfur dioxide in the gases leaving the installation, analyzer 16 of hydrogen sulfide in the incoming gas, actuators 20 and 22, torus 23

Description

The invention relates to devices for the automatic control of processes occurring in a fluidized bed, namely, the regulation of a predetermined ratio of oxidant-reagent and fluidization regime, and can be used in the processes of fuel combustion and oxidation in a fluidized bed of catalyst.

The purpose of the invention is to improve the quality of regulation.

The drawing shows a block diagram of the device.

A device for regulating the process in unit 1 comprises an air gas-distributing apparatus 2, a sulfur dioxide sensor 3 in the exhaust gases with an analyzer 4, a hydrogen sulfide in the exhaust gases 5 with an analyzer 6, a matching unit 7, a primary pressure converter 8 and a primary converter 9 temperature output gases from unit 1, primary converters 10 and 11 of the pressure and air temperature at the inlet of the installation, oxygen converter 12 in the air supplied to the installation, primary converters 13 and 14 of pressure and those hydrogen sulphide containing gas, hydrogen sulphide sensor 15 with analyzer 16, primary 17 and 18 converters of air flow and hydrogen sulphide containing air flow, computing unit 19, actuator 20 on the outgoing line from the air gas separation apparatus, oxygen concentration controller 21 in the incoming air, an actuator 22 on the air supply line, a regulator 23 of the ratio of the flow rates of hydrogen sulphide-containing gas and air, and a control circuit for the regime of fluidization and correction; ratios expenditure comprising waveguides 24, piezocer- nomic acoustic transducer 25, the block 26 rectifiers and the secondary device 27.

The device works as follows.

A given stoichiometric ratio of hydrogen sulfide gas to air is maintained by the controller 23 of the ratio of costs by the impact on the performer

a mechanism 22 for supplying air to the installation based on signals from the primary converters 18 and 17 of the flow of hydrogen sulfide gas and air flow.

The following scheme is applied to control and regulate the fluidized bed of the catalyst.

The signal characterizing the state of the fluidized bed waveguides 24

enters the acoustic piezoceramic transducer 25, from the output of the latter to the input of the rectifier unit 26, from the output of the rectifier unit 26, the signal is fed for control to the secondary device 27 and for adjustment to the corrective input of the ratio regulator 23. In the case of a change in the fluidization mode of the catalyst bed, the signal corresponding to this change, through the adjusting input of the regulator, will cause a change in the position of the actuator 22, which will lead to a change in air flow and, consequently, the flow dynamics until the catalyst bed is fully restored.

Unit 1 is supplied with air

air gas separation apparatus 2, for example, a membrane fiber air gas separation apparatus, in which it is enriched with oxygen to

concentrations of 40-80%, depending on the position of the actuator 20 on the outgoing flow line from the apparatus. At the same time, the total flow rate of the enriched stream remains constant. The signal to the actuator 20 is supplied by the regulator 21. an oxygen concentration, the input of which is associated with the output of the hydrogen sulfide analyzer 16 in the incoming hydrogen sulfide gas. The adjusting input of the controller 21 is associated with

the output of the computing unit 19, which, according to signals from the primary converters 14, 9, 13, 8 and 18, respectively, on temperature, pressure and flow, sensors 15.3 and 5 and analyzers 4 and 6, the concentration of hydrogen sulfide in

input stream, sulfur dioxide and hydrogen sulfide in the output stream calculates the required amount of oxygen, compares it with the amount of incoming signals from the primary converters 11, 10, 17, 12

based on temperature, pressure, flow rate, oxygen concentration in the air flow, and generates a resultant signal for adjusting the oxygen concentration regulator 21 in the air flow. Thus, the computing unit 19, together with the regulator 21, provides for the regulation of a predetermined hydrogen sulfide-oxygen ratio by varying the oxygen content in the incoming air within 40-80% more accurately depending on the change in the hydrogen sulfide concentration in the hydrogen-containing gas. Taking into account all factors; affecting the accuracy of the regulation of the hydrogen sulfide-oxygen ratio, the total air flow rate remains constant within the limits set by the regulator 23.

Claims (2)

Claim 1. Device for automatic perylation of the oxidation process in a fluidized bed installation, containing an analyzer of hydrogen sulfide concentration in the incoming hydrogen sulfide gas, a regulator of oxygen concentration in the incoming air flow, a ratio regulator of the flow rate of hydrogen sulfide gas and air with primary converters . an analyzer for the concentration of hydrogen sulphide and sulfurous anhydride in the gas flow, a unit for matching the analyzers of hydrogen sulphide and sulfuric anhydride with an oxygen concentration regulator, actuators for controlling the concentration of oxygen and controlling the air flow rate and an air gas separation device, the purpose of improving the quality of regulation, it additionally contains a computing unit, the output of which is connected to the corrective input of the concentrator controller and oxygen in the incoming air stream, and inputs - with primary transducers temperature, pressure and flow rate of incoming OSS. temperature and pressure of the effluent and analyzers of oxygen and hydrogen sulfide concentrations in the effluent and control circuit of the fluidization regime and correction of the flow ratio controller, the output of which is connected to the corrective input of the hydrogen sulfide-containing gas flow ratio and air and the secondary device. 2. Device pop. 1, characterized in that a measuring computer complex based on a mini-computer is used as a computing unit.