BRPI1100657A2 - fuel combustion method - Google Patents

Abstract

FUEL FUEL METHOD. Fuel combustion method using an existing air burner (1), which air burner (1) comprises a first fuel feed opening (5) and a second air feed opening (7), which feed openings ( 5, 7) communicate with a combustion zone (3). The present invention is characterized in that a gaseous fuel with a Lower Heating Value (LHV) of less than 7.5 MJ / Nm ^ 3 ^ is supplied through the second feed opening (7) and an oxidant comprising at least 85% by weight of oxygen also be supplied to the combustion zone (3) by means of an oxidizer feed device, and the gaseous fuel, together with oxidant, is burned in the combustion zone.

Description

"FUEL COMBUSTION METHOD"

The present invention relates to a method for combustion of fuel in an oven. Specifically, the present invention relates to a method of combustion of a low grade fuel in an oven.

In installations where industrial furnaces are used to produce steel and other metals, various types of low grade gaseous fuel are often obtained as by-products, such as, in one example, gas present in the upper portion of the blast furnace. (top-gas) that are used in steel production, or, in another example, off-gas. Such low grade fuels typically comprise a mixture of hydrocarbons, nitrogen, oxygen, hydrogen, carbon monoxide, and water vapor. Due to the often limited energy density of low grade fuels, these fuels are usually used in low temperature processes such as heating installations or power plants. Alternatively, these low grade fuels are blended with other medium and high grade fuels with higher energy density. Since such low grade fuels are often produced in abundance in steel mills, for example, being comparatively inexpensive, it would therefore be desirable to use them more extensively, including high temperature processes, for which processes are currently required. high grade fuels. Today low-grade fuels are often merely burned and dumped into the atmosphere to no avail.

The present invention addresses the problems described above. Thus, the present invention relates to a fuel combustion method using an existing burner, which burner comprises a first fuel feed opening and a second air supply opening, which openings communicate with a combustion zone, and which method is characterized in that a gaseous fuel with a Lower Heating Value (LHV) of less than 7.5 MJ / Nm3 is supplied through the second feed opening, and an oxidant comprising at least 85% oxygen by weight is also supplied to the combustion zone through an oxidizer feed device, and the gaseous fuel is burned together with the oxidizer in the combustion zone.

In the following the present invention will be described in detail with reference to exemplary embodiments and accompanying drawings in which:

Figure 1 is a contour diagram of an air burner using the method according to the present invention; and Figure 2 shows a contour diagram of a blast furnace and industrial furnace installed in the same plant.

Thus, Figure 1 illustrates a conventional air burner 1 which, in a conventional operation, is used to heat an industrial furnace. 0 burner a. Air 1 is mounted on an oven wall 2 of an industrial oven. In a conventional operation, air burner 1 is arranged to burn a fuel in the combustion zone with an oxidizer, which is air. During conventional operation, the fuel is supplied to the air burner by a supply duct 4, and thence to the combustion zone 3, through a fuel supply opening 5. The air is correspondingly supplied through the respective fuel duct. supply duct 6 and its air supply openings 7.

Air burner 1 may also be designed in other ways, which designs are conventional per se, such as using one or more air supply openings. The fuel used in a conventional operation may be either gaseous or liquid fuel. Conventional fuel consists of a medium or high grade fuel, such as liquefied petroleum gas, natural gas, or coke gas.

Thus, the present invention is not limited to the described embodiments, but rather which configurations may vary widely within the scope of the claims. Table 1 provides a typical content comparison of various constituents between a medium grade fuel such as coke-owen gas and a low grade fuel such as gas present in the upper portion of the blast furnace (top-gas) and converter gas (off-gas). All values being given in percent by volume._

N2 02 H2 CO CO2 CH4 CmHn H20 Coke oven gas 3.5 0.50 60 60 2.35 23.5 24 0.2 Blast furnace gas 52.5 0.5 55 2.3 23.5 5 1, 15 Converter Gas 17, 2 0.1 2.5 64, 5 15, 6 0.1

Table 2 provides a comparison between Lower Heat Values for coke oven gas, blast furnace gas, and converter gas .__

LHV (MJ · / Nmj) HHV (MJ / kg) Coke gas 17, 9 8.2 Blast furnace gas 3.2 4.3 Converter gas 7.5 10, 4

According. According to the present invention, conventional air burner 1 operates on gaseous fuel with a Lower Heating Value of 7.5 MJ / Nm3 or less. The fuel may comprise a certain admixture with another higher grade fuel as long as the Lower Heating Value of the mixture does not exceed 7.5 MJ / Nm3. However, for cost reasons, it is preferred not to admix 20 high grade fuels prior to combustion.

To compensate for the proposed Lower Heating Value of the fuel compared to conventional fuel, conventional air burner 1 does not operate using air as oxidant, but with an oxidant having a higher oxygen content than air. Preferably, the oxidant comprises at least 85 wt%, and more preferably at least 95 wt%.

By burning a low grade gaseous fuel together with such oxidant, flame temperatures and flue gas volumes, corresponding essentially to the flame temperatures and gas volume produced in a conventional combustion of a high grade fuel, can be achieved in the corresponding combustion energy. With this, inexpensive low grade fuels such as blast furnace gas in a suitable process can be used to heat an industrial furnace. It is preferable, in particular for the blast furnace gas case, that the amount of fuel supplied per unit of time essentially corresponds to the amount of air supplied in a conventional air burner operation. In other words, it is preferable that the amount of low grade fuel volume supplied per unit of time at a certain predetermined combustion energy be between half and two times, more preferably half and half times a time. amount of air volume used in a conventional air burner operation, supplying the same combustion energy. It is especially preferable that the amount of low grade fuel supplied per unit of time at a certain predetermined combustion energy is equal to the amount (± 10% of air volume) supplied in a conventional operation of an air burner providing same combustion energy.

In accordance with the present invention, low grade fuel is supplied to the combustion zone through the conventional air feed opening 7. It is also preferable, but not necessarily, that the air feed opening feed 7 is provided. made through the existing air supply duct 6. Since the volume flow of low grade fuel is relatively close to the air flow per unit of energy during conventional high grade fuel combustion, conventional feed duct 6 and conventional feed openings 7 can be used without having to implement no major modifications, and possibly even no modifications at all. This stems from the fact that the conventional air burner 1 can be converted to the use of a cheaper low grade fuel rather than a more expensive conventional high grade fuel without requiring any additional installation work. In addition, this results in the possibility of flexible operation, depending on access to various types of fuel.

Oxidant is also supplied to combustion zone 3, and low grade fuel is burned along with oxidant.

According to a first preferred embodiment, the oxidant is supplied through the existing fuel feed opening 5, preferably through the existing fuel feed duct 4. According to a second preferred embodiment, the oxidizer is supplied to the combustion zone 3 by an additional supply device 6, whose supply opening is arranged at a distance from both fuel supply opening 5 and air supply opening. 7, preferably arranged at a distance from the air burner orifice. This provides the advantage that an existing air burner can be adapted to produce either a normal flame or flameless combustion by arranging several different injection points for oxidant feed to the combustion zone 3.

According to a third preferred embodiment, the oxidant is partially supplied through the existing fuel feed opening 5 and supplemented by additional feed by the feed device 8, which must be large enough to provide the desired stoichiometric condition for the combustion zone. 3

It is preferable that the oxidant be supplied through a lance adapted for oxidant feed. This lance may be arranged, for example, within the fuel supply duct 4 and opening at a place near the fuel supply opening 5. Alternatively or additionally, the additionally arranged feeding device 8 may comprise such a lance.

Further, it is preferable that a high or medium grade fuel be injected into the combustion zone 3 at an early stage of burner operation 1 according to the present invention and ignited to initiate the combustion reaction between the low grade fuel. and oxidizing. Injection may be via the existing air burner 1, for example via the existing air supply port 7 or fuel supply port 5. It is also preferable, in case the air burner 1 comprises recuperator (not shown), conventional per se, to recover thermal energy by preheating the combustion air supplied by the feed opening 7, in view of the recuperator in operation. according to the present invention be connected to the low grade fuel stream so as to preheat the fuel. This provides greater combustion savings without having to implement any additional cost generating installations. Figure 2 schematically illustrates an industrial furnace 14 heated by a conventional air burner 1. In operation, according to a preferred embodiment of the present invention, an oxidant having a high oxygen content is fed from the feeder. oxidant 14 to burner 1 through duct 13 and supplied to combustion zone 3 as described above. The fuel is supplied to the burner 1 through another duct 11 from the blast furnace 10. The fuel supplied from the blast furnace 10 consists of blast furnace gas produced in the operation of the blast furnace 10. Possibly, the fuel from The blast furnace is mixed with an additional gaseous fuel, preferably one or more low grade fuels. It is preferable that at least half of the combustion energy supplied from the burner 1 comes from the blast furnace gas.

In addition, it is preferable that at least half or more, and preferably all low grade fuel burned in burner 1, be or have been produced and therefore originate from the operation of equipment installed in the same industrial installation as the installation in which the burner 1 is found. It is especially preferred that the fuel consists of a blast furnace gas originating from the operation of a blast furnace 10 arranged in the same industrial installation as burner 1.

This method results in the recapture of energy being done in the same facility, as well as keeping the total cost of the facility's operations low, and reducing the need for transportation.

It is preferred that the burner 1 is operated to heat an industrial furnace 14 to a temperature above 500 ° C, preferably at and above TO0 ° C, and more preferably above 800 ° C. It is also preferable that the industrial furnace 14 be operated in several steps for producing or treating a metal, preferably steel. It is especially preferred that the industrial furnace 14 constitute or comprise a flowing stream, annealing line, or bucket preheat oven.

In accordance with the present invention, air burner 1 does not operate on medium and high grade fuel, but instead uses a low grade gaseous fuel such as blast furnace gas. Above, preferred configurations have been described, however, it should be apparent to those skilled in the art that a number of modifications may be introduced to the described configurations without departing from the inventive concept. By way of example, several different types of blast furnace-like units generating low grade gaseous fuels may be connected to one or more burners. Thus, the present invention is not described but may vary in the appended claims. air.

limited to configurations within the scope of the

Claims (10)

1. A fuel combustion method using an existing air burner (1) which comprises a first fuel feed opening (5) and a second air feed opening (7), such fuel supply openings. fuel and air (5, 7) being opened in a combustion zone (3), said method being characterized by the fact that a gaseous fuel having a Lower Heating Value (LHV) of less than 7.5 MJ / Nm3 is supplied through the second feed opening (7), and an oxidant comprising at least 85 wt% oxygen is also supplied to the combustion zone (3) via an oxidant feed device, and in which the gaseous fuel is carried. combustion with oxidant in the combustion zone (3). Method according to claim 1, characterized in that the oxidant feed device comprises a lance adapted to provide an oxidant. Method according to claim 2, characterized in that a lance is arranged at a distance from both first and second openings (5, 7) in the air burner (1), and that the oxidant is partially or partially supplied. totally through the said spear. Method according to any one of claims 1 to 3, characterized in that the oxidant feed device is arranged so that the oxidant is partially or wholly supplied through the existing first fuel feed opening (5). on the air burner (1). Method according to any one of claims 1 to 4, characterized in that the combustion reaction between the oxidant and a low grade fuel is used to heat an industrial furnace (14). Method according to any one of claims 1 to 5, characterized in that the amount of fuel supplied per unit of time in a predetermined energy corresponds to the amount of air supplied which is supplied per unit of time during conventional air burner operation (1). Method according to any one of claims 1 to 6, characterized in that, at an initial stage, a high or medium grade fuel is introduced through the air burner (1) and burned in the combustion zone. (3), so that combustion of low grade fuel is initiated. Method according to any one of claims 1 to 7, characterized in that at least half of the fuel consists of gas collected from the upper portion of the blast furnace (10). Method according to claim 8, characterized in that the flue gas originates from the operation of a blast furnace (1) arranged in the same industrial installation as the air burner (1). Method according to any one of claims 1 to 9, characterized in that an existing recuperator which during normal operation of the air burner (1) is used to preheat the combustion air instead of , to be used to preheat the fuel.