SK367392A3 - Method of working of industrial furnaces - Google Patents

Abstract

A procedure for operating industrial furnaces is provided, whose waste gases are burned in the waste gas line. According to the invention, the temperature of the waste gas is continuously measured and, when a preset value of the measured waste gas temperature is exceeded, the oxygen content of the atmosphere of the industrial furnace is increased. This has the result that the carbon monoxide released in the furnace and the hydrogen are burned under control already in the furnace and not only in the waste gas line. In this way, energy for heating the industrial furnace can be saved and downstream filter installations are thermally protected.

Description

Technical field

BACKGROUND OF THE INVENTION The present invention relates to a method for the operation of industrial furnaces, wherein the flue gases burn in a flue gas duct.

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BACKGROUND OF THE INVENTION

In foundries and equipment for the conversion of cast iron, media, lead, aluminum and other metals are very often used! Melting furnaces heated by burners. For example, if a molten steel is melted in a rotary drum furnace, a worm of 2-10 tons is heated by oil or gas burners in a horizontally mounted, refractory lined, slowly rotating drum about a longitudinal axis to a tapping temperature of about 1500 ° C. Heating of rotary drum furnaces is mostly carried out by burners which are arranged on the front side of the furnace and whose flame reaches inside the furnace. Through the opening arranged most often on the opposite side of the furnace, the flue gases escape from the furnace through a pipe to the chimney.

In the operation of such industrial furnaces, large amounts of carbon monoxide are present in the flue gas, the amount of carbon monoxide released being dependent on the oxygen content of the furnace, the temperature of the furnace, the furnace being melted, the rotary motion of the furnace, and the optional means for controlling the carbon content. In addition to the carbon monoxide, hydrogen is also present in a small proportion of the flue gas leaving the furnace, which requires oxygen to burn it. Hydrogen comes from combustion reactions, from fuel, and from plastic materials and oils that often adhere to the charge.

So far, the carbon monoxide and hydrogen contained in the flue gas of an industrial furnace have been combusted in the flue gas ducts. The generation of flames in the flue gas ducts leads to a severe thermal load on the downstream filters. The fabric filters overheat or the filter device is disconnected.

In addition, the combustion of carbon monoxide in the flue gas ducts is energy-unfriendly for the transport of an industrial furnace. Efforts to burn carbon monoxide in the furnace interior would be significant. Such released energy could then lead to fuel savings.

Due to the strongly fluctuating amount of carbon monoxide released in the furnace, the controlled combustion of carbon monoxide has not yet been possible. Indeed, the oxygen supply to the furnace would still have to be correlated

-2 with the amount of carbon monoxide released. The same applies to hydrogen released in a substantially smaller amount. On the other hand, in the case of a continuous excess of oxygen, the alloying elements are burned, for example in the case of molten iron. Long-term use of the gas analyzer _f MCRI that the content of CO in the furnace atmosphere, it is not possible from the generation of dust and dflvodfl Eazi, which are deposited particles of the water-cooled sensors, analyzers and mčŕicích ústrcjích.

Accordingly, it is an object of the present invention to provide an improved method for conveying industrial furnaces whose combustion gases are burnt in the flue gas ducts to overcome the aforementioned drawbacks of the prior art and to make the furnace more energy efficient and reduce the thermal stress of the filters. flue gas.

SUMMARY OF THE INVENTION

SUMMARY OF THE INVENTION The invention solves the problem by providing a method for the operation of industrial furnaces whose combustion gases are burnt in the flue gas duct, the principle being that the temperature of the combustion gases is continuously measured and the oxygen content of the atmosphere is exceeded. industrial furnaces.

Tightening of the carbon monoxide content of the flue gas on the side of the flue gas from the furnace and the wasting of the temperature in the flue gas duct to the chimney show that both values are directly related.

This connection will be further clarified in the case in which the carbon monoxide contained in the flue gas as well as hydrogen is combusted by air which may enter the flue gas ducts through openings:

At a low carbon monoxide content in the flue gas, the bulk of this material is cooled by the air entering the flue gas duct, whereby the flue gas temperature also remains low. At a high carbon monoxide content in the flue gas, the carbon monoxide is predominantly burned in the feed air oxygen, so that there is no cooling of the flue gas. The temperature of the flue gas can then be higher than 600 ° C when the cast iron is changed. The same applies to

An oxidant other than air is used to burn the flue gas in the flue gas duct.

According to the invention, the temperature of the flue gas at one point in the pipe to the cone can be compared with the relative content of the carbon monoxide in the darkness of the furnace. thereby providing a simple and non-controlling method for continuously detecting the carbon monoxide content within the furnace.

The deployment of gas quantity measuring devices for determining the carbon monoxide content within the furnace, which are failing and costly to maintain, will become wholly unnecessary using the method of the invention.

The present invention allows the advantageous control of the combustion of carbon monoxide released in the atmosphere of industrial furnaces. All processes which produce carbon monoxide and hydrogen in the furnace atmosphere and which are subsequently burnt in the flue gas are considered. To the controlled combustion of carbon monoxide and hydrogen, the oxygen content in the furnace atmosphere is increased when the predetermined setpoints of the measured flue gas temperature are exceeded.

The proportion of oxygen in the furnace atmosphere may be introduced into the furnace by direct injection of oxygen through the nozzles to increase the oxygen content of the furnace. Any oxygen-containing gas may also be used. In industrial furnaces heated by oxygen and fuel burners, oxygen can advantageously be fed to the interior of the furnace via the burner. If the measured flue gas temperature exceeds a predetermined setpoint, additional oxygen is introduced into the furnace interior corresponding to the control path until the flue gas temperature again falls below the setpoint.

Carbon monoxide and hydrogen, which are burned inside the furnace, release energy and raise the temperature in the industrial furnace. This leads to twisted process times as well as energy savings. In addition, the proportion of carbon monoxide in the flue gas is reduced, thereby lowering the temperature of the flue gas and the further connected flue gas filters can no longer be thermally overloaded.

Otherwise, the amount of fuel to be supplied to the burners can also be reduced at a predetermined amount of oxygen when the preset setpoint temperature of the flue gas is exceeded. This results in primary fuel savings when the industrial furnace is heated.

The appropriate temperature reference is correctly determined when the industrial furnace is first started by experiment. For this purpose, a thermocouple can be provided, for example, behind the last opening for air or other oxidant in the flue gas duct. The temperature of the flue gases combusted by the air or oxidant is then determined. This temperature corresponds to the relative content of carbon monoxide and hydrogen in the furnace interior. Depending on the operating mode of the industrial furnace, no value is selected in the range of from 120 to 650 ° C. 250 C.

--4 Overview of figures and drawings

In a single figure, there is shown schematically a device for operating a method of operating an industrial furnace according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

An industrial furnace 1, in particular designed as a rotary drum furnace, is discharged by a burner 2 connected to an oxygen supply line 2 and a fuel supply line. The industrial furnace 1 is connected to a flue gas duct 10 having air gaps 6 and J. Downstream of the second air gap X, a thermocouple 8 is connected to the receiver 2 of the measured values inside the flue gas duct 10.

The melting of cast iron in the industrial furnace 1 comprises at the 5-bet by weight of 3 t ^0, which is heated by the burner 2 to the oil O in about 2.5 p to about 1500 ° C for tapping.

The carbon contained in batch 2 ^is oxidized during the melting process with the furnace atmosphere partially to carbon monoxide and carbon dioxide, so that a means to increase the carbon content must be added to the batch to compensate for the loss of carbon. In this example, the determination of the carbon monoxide content of the dry flue gas gives a maximum value of 35% of the carbon monoxide in the flue gas directly on the front side of the furnace.

First, thermocouple 8 and receiver g. The measured values measure for a certain time the temperature of the flue gas burned by the air in the flue gas duct 10. Depending on the length of the exhaust gas duct 10 downstream of the thermocouple 8, temperatures of 150 ° C to 250 ° C are suitable. In this case, a setpoint of 230 ° C is set on a controller (not shown). This regulator is connected to a control valve inserted in the oxygen supply line 2 to the burner 2.

If the measured temperature now exceeds a predetermined setpoint temperature, according to the invention, the proportion of oxygen in the atmosphere of the industrial furnace 1 is increased. This is achieved by the stoichiometric combustion of the fuel-oxygen mixture in the industrial furnace 1. inside the furnace, it exceeds a certain threshold, increasing the oxygen supply to the burner 2 so that carbon monoxide can be completely oxidized to carbon dioxide and hydrogen is burned. The energy released so far in the flue gas duct 10 is already released in the jet furnace 1 according to the invention.

This reduces the flue gas temperature and reduces the oxygen supply to the burner 2 again.

The combustion of carbon monoxide in an industrial furnace, in particular in a rotary drum furnace according to the invention, has several advantages.

The released energy of combustion of the carbon monoxide can still be utilized in an industrial furnace with decreasing carbon monoxide content in the industrial furnace and limits the oxygen supply, so that the combustion of the alloying elements is prevented. The flue gas temperature is lower throughout the operation of the industrial furnace, so that the filters are no longer overloaded. The volume of flue gas is reduced since carbon monoxide is applied in an industrial furnace 1 with oxygen mixed in the air exhaust duct 10. Finally, the method of the invention uses a simple temperature measurement to determine the relative carbon monoxide content of an industrial furnace 1 instead of a technically difficult to handle analysis in the furnace atmosphere.

Claims (7)

PATENT CLAIMS A method for operating industrial furnaces whose combustion gases are incinerated in a flue gas duct, characterized in that the temperature of the furnace is continuously measured and the oxygen content of the furnace atmosphere is increased when the predetermined desired value of the measured combustion gas temperature is exceeded. 2. The process according to claim 1, wherein an oxygen-containing gas or a pure oxygen gas is introduced into the atmosphere of the industrial furnace when the predetermined values of the measured flue gas temperature are exceeded. 3. The process according to claim 1 or 2 for industrial furnaces which are oxygen and fuel burners, characterized in that the amount of oxygen supplied to the burners is increased when the predetermined setpoints of the measured flue gas temperature are exceeded. 4. A process according to any one of claims 1 to 3 for industrial furnaces heated by oxygen and fuel burners, characterized in that the amount of fuel supplied to the burners is reduced when the predetermined setpoints of the measured flue gas temperature are exceeded. 5. A method share of any of claims 1 to 4, P ^R industrial furnaces for smelting cast iron, characterized in that the desired value of the measured exhaust gas temperature is preferably selected in the range 150 to 250 ° C. 6. A method according to any one of claims 1 to 5, wherein the flue gases from the industrial furnace are incinerated with a vent entering the flue gas duct. 7. A method according to any one of items 1 to 6, wherein: The flue gas from an industrial furnace is epalysed with an oxidant introduced into the flue gas duct.