Method for operating a gas turbine burner with a swirl generator

What is claimed is: 1. A method for operating a burner having a swirl generator defined by at least two walls facing one another to define a substantially conical swirl chamber, the swirl generator including swirl generator nozzles arranged to inject fuel and apertures arranged to feed an oxidizer into said swirl chamber, a mixing tube positioned downstream of the swirl generator, and a lance positioned inside at least the swirl generator, the lance extending along a longitudinal axis of the swirl generator and being provided with lance side nozzles for ejecting gaseous fuel within the burner, the lance side nozzles having axes inclined with respect to an axis of the lance, wherein the lance includes one of an annular protrusion extending from and encircling an outer surface of a body of the lance or an inner surface of a lid encircling the body of the lance, the method comprising: at starting, injecting about 70-80% of the gaseous fuel through the lance tip nozzle, injecting about 20% through the lance side nozzles, and injecting about 0-10% of the gaseous fuel through the swirl generator nozzles; at idle operation, injecting about 70% of the gaseous fuel through the lance tip nozzle, injecting about 20% of the gaseous fuel through the lance side nozzles, and injecting about 10% of the gaseous fuel through the swirl generator nozzles; at part load, injecting about 40% of the gaseous fuel through the lance tip nozzle, injecting about 20% of the gaseous fuel through the lance side nozzles, and injecting about 40% of the gaseous fuel through the swirl generator nozzles; and at full load, injecting about 5% of the gaseous fuel through the lance tip nozzle, injecting about 20% of the gaseous fuel through the lance side nozzles, and injecting about 75% of the gaseous fuel through the swirl generator nozzles; wherein the gaseous fuel injected through the lance side nozzles is injected against the one of the annular protrusion or the inner surface of the lid as the gaseous fuel exits the lance side nozzles. 2. The method of claim 1 , wherein the gaseous fuel is injected against the inner surface of the lid as the gaseous fuel exits the lance side nozzles, and the lance side nozzles are disposed at an acute angle with respect to the axis of the lance. 3. The method of claim 1 , wherein the gaseous fuel is injected against the annular protrusion as the gaseous fuel exits the lance side nozzles, and the lance side nozzles are disposed at an acute angle with respect to the axis of the lance. 4. A method for operating a burner having a swirl generator defined by at least two walls facing one another to define a substantially conical swirl chamber, the swirl generator including swirl generator nozzles arranged to inject fuel and apertures arranged to feed an oxidizer into said swirl chamber, a mixing tube positioned downstream of the swirl generator, and a lance positioned inside at least the swirl generator, the lance extending along a longitudinal axis of the swirl generator and being provided with lance side nozzles for ejecting fuel within the burner, the lance side nozzles having axes inclined with respect to an axis of the lance, wherein the lance includes an annular protrusion extending from and encircling an outer surface of a body of the lance, the method comprising: during operation with oil fuel: at starting, injecting about 80% of the oil fuel through a lance tip nozzle and injecting about 20% of the oil fuel through the lance side nozzles; at idle operation, injecting about 75% of the oil fuel through the lance tip nozzle and injecting about 25% of the oil fuel through the lance side nozzles; at part load, injecting about 50% of the oil fuel through the lance tip nozzle and injecting about 50% of the oil fuel through the lance side nozzles; at full load, injecting about 10% of the oil fuel through the lance tip nozzle and injecting about 90% of the oil fuel through the lance side nozzles; and, wherein the oil fuel injected through the lance side nozzles is injected against the annular protrusion as the oil fuel exits the lance side nozzles; and, during operation with gaseous fuel: at starting, injecting about 70-80% of the gaseous fuel through the lance tip nozzle, injecting about 20% of the gaseous fuel through the lance side nozzles, and injecting about 0-10% of the gaseous fuel through the swirl generator nozzles; at idle operation, injecting about 70% of the gaseous fuel through the lance tip nozzle, injecting about 20% of the gaseous fuel through the lance side nozzles, and injecting about 10% of the gaseous fuel through the swirl generator nozzles; at part load, injecting about 40% of the gaseous fuel through the lance tip nozzle, injecting about 20% of the gaseous fuel through the lance side nozzles, and injecting about 40% of the gaseous fuel through the swirl generator nozzles; and at full load, injecting about 5% of the gaseous fuel through the lance tip nozzle, injecting about 20% of the gaseous fuel through the lance side nozzles, and injecting about 15% of the gaseous fuel through the swirl generator nozzles; wherein the gaseous fuel injected through the lance side nozzles is injected against the annular protrusion as the gaseous fuel exits the lance side nozzles. 5. The method of claim 4 , wherein the lance side nozzles are disposed at an acute angle with respect to the axis of the lance, the method comprising: during the operation with oil fuel: generating a cylindrical fuel film encircling the lance via the oil fuel injected from the lance side nozzles. 6. The method of claim 4 , wherein the lance side nozzles are disposed at an acute angle with respect to the axis of the lance, the method comprising: during the operation with oil fuel; generating a discrete fuel film encircling the lance via the oil fuel injected from the lance side nozzles. 7. The method of claim 4 , comprising: during the operation with oil fuel: injecting the oil fuel through the lance tip nozzle along an axis of the burner so that a cloud of fuel droplets is concentrated along the axis of the burner. 8. The method of claim 4 , comprising: during the operation with gaseous fuel: dragging away the gaseous fuel injected by the lance side nozzles via air flow towards an annular periphery of the swirl chamber and the mixing tube. 9. A method for operating a burner having a swirl generator defined by at least two walls facing one another to define a substantially conical swirl chamber, the swirl generator including swirl generator nozzles arranged to inject fuel and apertures arranged to feed an oxidizer into said swirl chamber, a mixing tube positioned downstream of the swirl generator, and a lance positioned inside at least the swirl generator, the lance extending along a longitudinal axis of the swirl generator and being provided with lance side nozzles for ejecting fuel within the burner, the lance side nozzles having axes inclined with respect to an axis of the lance, wherein the lance includes an inner surface of a lid encircling a body of the lance, and the lance side nozzles are disposed at an acute angle with respect to the longitudinal axis of the lance, the method comprising: during operation with oil fuel: at starting, injecting about 80% of the oil fuel through a lance tip nozzle and injecting about 20% of the oil fuel through the lance side nozzles; at idle operation, injecting about 75% of the oil fuel through the lance tip nozzle and injecting about 25% of the oil fuel through the lance side nozzles; at part load, injecting about 50% of the oil fuel through the lance tip nozzle and injecting about 50% of the oil fuel through the lance side nozzles; at full load, injecting about 10% of the oil fuel through t