KR840000649B1 - A method of heating coke ovens - Google Patents

Abstract

Regenerative coke ovens with connections for sending unpreheated gas to the heating flues have burners for rich gas with a high hydrocarbon content that protrude in the flues. The walls of the burners, as well as the supply tubes located in the hot parts of the oven, are made of a refractory material that has a smooth surface. This eliminates the difficulties of graphite deposition on rough surfaces of burners and their supply pipes so that special measures to remove the deposits become unnecessary.

Description

How to heat coke oven

The present invention relates to a method of heating a coke oven with by-product gas containing a relatively lean gas of various composition ratios as a method of regenerative heat exchange between combustion air and combusted gas. .

When operating coke ovens in steel products or other facilities, a variety of gases with lower calories than by-product gases are produced. Therefore, attempts have been made to utilize coal by-product gas for various purposes. The coke oven can be operated with a mixture of moderate rich gas and relatively lean gas, and rich until the mixed gas of rich gas and lean gas has a caloric value of 2500 or more (preferably 3000kcal / m ³ ). The gas can be diluted with lean gas. A further reduction in calorie value leads to lower thermal efficiency, and this method is suitable for ovens using only rich gas, since preheating in regenerators does not occur when using rinse gas.

The present invention relates to a coke oven in which the mixed gas is moved in a conventional manner through a rich gas heating device. However, due to the large amount of gas and the large weight, more pressure is required than when only rich gas is used. It is necessary to keep the pressure to a minimum to prevent the risk of gas leaks through the diverting and blocking devices. In fact, the pressure in the piping is about 120-150 mm WC (Water Column) and the pressure in the so-called "nozzle piping" extending into the compartment in the underjet 5 minutes is under 100 mm WC.

When the pressure on the mixed gas containing the maximum amount of lean gas is set and the nozzle on the heating wall is able to withstand until the nozzle pipeline pressure is about 90 mm WC, the pressure drop generated during heating conversion to rich gas is very large. Rich gas cannot be effectively distributed to the heating wall between each burner.

The nozzles cannot be converted to cross-section when the heat heated with different gas mixtures or gases is switched but moved.

Therefore, according to the present invention, the pressure in the main pipe is set at a corresponding value such that the lean gas forming the mixture has a maximum mixing ratio, wherein the addition of the lean gas is reduced or stopped so that the caloric value of the mixed gas is reduced. If elevated, the increased heat supply to the oven can be compensated by stopping the heating at the interval of each regeneration cycle. Interval may be long or short depending on whether the mixed gas calorie value rises or falls as a result of the reduced mixture with lean gas. By operating in this way, optimum control over all properties of the gas mixture can be achieved without changing the cross section of the nozzle or other control device, where the control device is the main element controlling the distribution. In order to change the interval between intervals in the reproduction half, it is necessary to install a converter. Therefore, if the calorie value of the mixed gas changes during operation, it is necessary to stop the operation or change the operation by adjusting the device installed in the conversion value Winch.

It is already known how to stop heating during each regeneration cycle. For example, the stopping action is achieved by converting the flue gas throttling device in the piping between the normal exhaust pipe and the communication to a position where the suction in the normal exhaust pipe is reduced after the gas cock is closed.

That is, the interruption of heating is made by first closing the gas scotch and then moving all the air valves and the flue gas valves to the central position.

This new method of heating can be described vertically as follows:

Given calorie value of rich gas: Hu = 4500kcal / Nm ³

Weight: = 0.4kg / Nm ³

Given calorie value of lean gas: Hu = 700 kcal / Nm ³

Weight: = 1.2kg / Nm ³

Using a given density and calorie value of rich gas and lean gas, about 60% rich gas should be mixed with 40% lean gas to obtain a mixed gas having a calorie value of Hu = 3000 kcal / Nm ³ . The weight of the mixed gas is 0.72 kg / Nm ³ .

The amount of heat transferred while heating the mixed gas is the same as the amount of heat when only the rich gas is heated. In a series of rich gas nozzles, the mixed gas pressure is 90 mmWC, while the pressure when heated only with rich gas is 22 mmVC. This is insufficient to effectively distribute the rich gas to each burner in the heating wall. To raise the pressure to 90mmWC, the volumetric flow of gas must be doubled. That is, twice the amount of rich gas must be moved along a series of nozzles to maintain a constant pressure of 90 mmWC.

The regeneration ban for 30 minutes is a time for maintaining the same heat supply as the mixed gas heating during each regeneration ban, which is the same time as the 15 minute cessation when heating only with the rich gas. If the mixed gas used for heating has a higher calorie value, that is, if a smaller amount of lean gas is mixed with the rich gas, the interruption of heating will be relatively short.

Claims (1)

When the mixed gas is formed, the pressure in the pipe is kept constant at a corresponding value so that the lean gas can be formed at the maximum mixing ratio, and when the addition of the lean gas is reduced or stopped, the amount of heat supplied to the oven is reduced to the interval between each regeneration cycle. A method of heating a coke oven with by-product gas in which lean gas is mixed in various ratios by means of a regenerative heat exchange method between combustion air and combusted gas, characterized in that it is canceled by stopping heating.