SU1749235A1 - Method of diagnostics of fluid-tightness of lower gas-sealing valve of cone-free charging apparatus - Google Patents

Abstract

The invention relates to ferrous metallurgy and can be used on blast furnaces equipped with infinite loading devices. In the proposed method, the diagnostics of the tightness of the lower sealing valves results in the occurrence of an atmospheric pressure drop in a closed valve box between the lower gas sealing valve and the compacted charge gate. This allows timely detection of depressurization and taking measures to eliminate it. 1 il.

Description

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The invention relates to ferrous metallurgy, in particular, to the domain production, and can be used on blast furnaces equipped with coneless loading devices with various types of distributors.

Methods are known for diagnosing the tightness of the lower sealing valves of infinite loading devices, including inspection of the surfaces of the seat and the plate, checking the integrity of the sealing element, as well as the gap between the contact surfaces.

The closest to the invention to the technical essence and the achieved result is a well-known method for diagnosing tightness of bottom sealing valves of infinite charging devices, including closing the charge gate and lower sealing valve, equalizing the pressure in the bunker with atmospheric after unloading the charge from the bunker, opening the upper valve mechanisms of the upper gas sealing valve, the receiving funnel shutter and filling the hopper with charge material. After that, the receiving funnel flap, the upper gas sealing valve are closed and, if the pressure is increased in the bunker with the discharge and filling valves closed for some time, this is the reason for the failure of the lower sealing valve.

A disadvantage of the known methods is to reduce the rate of loading of the furnace with charge materials due to delays (when checking the depressurization) in the time required to create pressure in the bunker due to depressurization of the valve. With

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this, the less blowing, the more time should be spent on the diagnosis of valve tightness. In addition, the operation should be repeated when the next batch is loaded into the hopper in order to eliminate the effect of material getting between the plate and the saddle when the valve is closed. Thus, the delay time doubles, which leads to a decrease in the stability of the blast smelting process, production losses, and an increase in coke consumption. Inspection of contact surfaces with the opening of special hatches requires, for example, for devices of the company P. Würth, stopping the furnace with cutting off both paths, and for the VNIIMETMASH design - exclusion from the work of one path with decrease in the loading system capacity. Late detection of depressurization of the lower sealing valves, reducing their maintainability increases harmful emissions into the atmosphere.

The speed of detecting depressurization in the known methods largely depends on the experience and technological discipline of the operating personnel. At the same time, one of the main environmental requirements for charging devices for blast furnaces is the tightness of charge and gas paths.

The aim of the invention is the efficiency of diagnostics of tightness of the lower sealing valve of a cone-loading device.

The goal is achieved by the fact that according to the diagnostic method, which includes closing the bottom gas sealing valve and charge gate, pressure equalization in the bunker with respect to atmospheric pressure, measuring pressure in the bunker, filling it with charge, pressure is measured in a closed valve box between the bottom gas sealing valve and the charge gate, and the depressurization is fixed when the measured pressure exceeds the atmospheric pressure.

The drawing shows the discharge part of the hopper of the boot device, a cross-section.

The device contains a closed valve box 1, charge valve 2, the lower sealing valve 3, the pressure sensor 4 and the base of the hopper 5

The method is carried out as follows.

After unloading into the furnace from the hopper 5 of the portion of the charge material, the charge valve 2 and the lower gas sealing valve 3 are closed, the pressure in

the bunker is aligned with the atmospheric one, the top sealing valve and the receiving hopper valve (not shown) are opened and the next portion of material begins to be loaded into the bunker 5, sealing

charge valve 2. If the lower sealing valve 3 is leaky, then in a closed sealed valve box 1 between the compacted charge gate 2 and valve 3 is formed

overpressure, which is detected by sensor 4, and a signal on depressurization of valve 3 will be sent to the automated control system

At the beginning of depressurization, an overpressure of at least 0.01 MPa is taken, i.e. the magnitude of the sensitivity limit of the instrument used.

According to the proposed method, the diagnostics of tightness automatically leads to the appearance of a pressure drop in relation to the atmospheric closed valve box between the lower gas sealing valve and the compacted charge charge valve. This allows

detect depressurization in a timely manner and take measures to eliminate it.

The application of the method allows to eliminate downtime for diagnostics of tightness of the lower sealing valves and,

thus, to increase the productivity of blast furnaces and reduce fuel consumption. Timely detection of depressurization increases the maintainability of valves, and also increases environmental

process cleanliness.

Claims (1)

Claim method for diagnosing tightness of the lower gas sealing valve of a conical charging device for a blast furnace, including closing the lower gas sealing valve and charging gate, equalizing the pressure in the bunker with respect to atmospheric, measuring pressure in the bunker, filling it with a charge, characterized in that, in order to increase efficiency, the pressure is measured in a closed valve box between the lower pelvic sealing valve and with charge gate a depressurization is fixed when the measured value exceeds the atmospheric pressure. five