초록 ▼

The invention concerns a method for burning a fuel by means of at least one a burner, each burner comprising two half-assemblies (1, 1′) comprising each at least one fuel injecting means (2) associated with a primary oxidant injecting means (3), and at least one secondary oxidant injecting means (4)

The invention concerns a method for burning a fuel by means of at least one a burner, each burner comprising two half-assemblies (1, 1′) comprising each at least one fuel injecting means (2) associated with a primary oxidant injecting means (3), and at least one secondary oxidant injecting means (4), a first oxidant jet being injected at a first distance from the fuel by the primary injecting means so as to generate a first incomplete combustion, and a second oxidant jet being injected at a second distance (L1), greater than the first distance, from the fuel injecting means so as to generate a second combustion with the remaining fuel of the first incomplete combustion. Said method is characterized in that each half-assembly delivers a combustion power different from the one delivered by the other half-assembly.

대표청구항 ▼

1. A method for the combustion of a fuel by means of a burner, said burner having two semi-assemblies, each semi-assembly comprising: a) at least one fuel injection means;b) a primary oxidizer injection means; andc) at least one secondary oxidizer injection means, said method comprising the steps of

1. A method for the combustion of a fuel by means of a burner, said burner having two semi-assemblies, each semi-assembly comprising: a) at least one fuel injection means;b) a primary oxidizer injection means; andc) at least one secondary oxidizer injection means, said method comprising the steps of:injecting a first oxidizer jet at a first distance from the fuel by the primary injection means so as to produce an incomplete first combustion, andinjecting a second oxidizer jet at a second distance from the means for injecting fuel by the secondary injection means so as to produce a second combustion with fuel remaining from the incomplete first combustion, said second distance being greater than the first distance, wherein: each semi-assembly delivers a different combustion power from that delivered by the other semi-assembly;the two semi-assemblies are distributed symmetrically about an axis of symmetry S; andthe first combustion and second combustion of each of said two semi-assemblies forming a flame that is asymmetric with respect to said axis of symmetry S. 2. The method of claim 1, wherein a third oxidizer jet is injected at a third distance greater than the first distance by a tertiary oxidizer injection means. 3. The method of claim 1, wherein a different quantity of fuel is injected into the fuel injection means of each semi-assembly. 4. The method of claim 1, wherein the burner creates a flame close to a wall and in that the power of the semi-assembly nearest to said wall possesses the smallest combustion power. 5. A method for heating a material in a furnace, said furnace being fitted with at least one pair of burners, the burners of said pair being placed face-to-face in the furnace, each of said burners having first and second semi-assemblies, each of said first and second semi-assemblies comprising at least one fuel injection means, a primary oxidizer injection means, and at least one secondary oxidizer injection means, said method comprising the steps of: injecting a first oxidizer jet at a first distance from the fuel by the primary injection means so as to produce an incomplete first combustion; andinjecting a second oxidizer jet at a second distance from the means for injecting fuel by the secondary injection means so as to produce a second combustion with fuel remaining from the incomplete first combustion, said second distance being greater than the first distance, wherein:a) for each of said burners, the first semi-assembly delivers a lower combustion power from that delivered by the second semi-assembly;b) the burners of the pair are arranged in the furnace so that each semi-assembly of a burner is facing a semi-assembly of the other burner of the pair; andc) the first semi-assembly of the first burner of the pair faces the second semi-assembly of the second burner of the pair. 6. The method of claim 5, wherein, for each burner, the combustion power of each semi-assembly is less than 0.8 times the total power of said burner. 7. The method of claim 5, wherein, for burners of the same pair, the second semi-assembly operates with a combustion stoichiometry greater than 1 and the first semi-assembly placed facing this over-stoichiometric semi-assembly operates with a combustion stoichiometry less than 1. 8. A method for heating a material in a furnace, said furnace being fitted with at least one pair of burners, the burners of said pair being placed face-to-face in the furnace, each of said burners having first and second semi-assemblies, each of said first and second semi-assemblies comprising at least one fuel injection means, a primary oxidizer injection means, and at least one secondary oxidizer injection means, said method comprising the steps of: injecting a first oxidizer jet at a first distance from the fuel by the primary injection means so as to produce an incomplete first combustion; andinjecting a second oxidizer jet at a second distance from the means for injecting fuel by the secondary injection means so as to produce a second combustion with fuel remaining from the incomplete first combustion, said second distance being greater than the first distance, wherein:a) for each of said burners, the first semi-assembly delivers a lower combustion power from that delivered by the second semi-assembly;b) the burners of the pair are arranged in the furnace so that, for each burner, only one of its semi-assemblies faces a semi-assembly of the other burner of the pair; andc) the first semi-assembly of the first burner of the pair faces the semi-assembly of the second burner of the pair. 9. The method of claim 8, wherein, for each burner, the combustion power of each semi-assembly is less than 0.8 times the total power of said burner. 10. The method of claim 8, wherein, for the burners of the same pair, the second semi-assembly operates with a combustion stoichiometry greater than 1 and the first semi-assembly placed facing this over-stoichiometric semi-assembly operates with a combustion stoichiometry less than 1.