Mineral fiber forming device

The invention claimed is: 1. A mineral fiber forming device for producing an insulating product comprising: a molten glass feeding system configured to supply molten glass; a hollow shaft having a top end coupled to the molten glass feeding system so as to receive the molten glass, a centrifuge coupled to a bottom end of the hollow shaft so that the molten glass flows into the hollow shaft until the molten glass arrives into the centrifuge when the device is in operation, the hollow shaft having a same axis of symmetry as the centrifuge, the centrifuge being configurated to rotate about a rotation axis, the centrifuge comprising an annular wall pierced by a plurality of orifices, an axis of symmetry of the annular wall being the rotation axis, and the annular wall having a height, a first annular inductor positioned above the annular wall and configured to heat a top area of the annular wall to generate a first heating zone on said annular wall, a second annular inductor comprising one or more coils, the second annular inductor positioned below a bottom of the annular wall such that each of the one or more coils is positioned below the annular wall pierced by a plurality of orifices and such that the second annular inductor is configured to heat a bottom area of the annular wall to generate a second heating zone on said annular wall, one or more power generators adapted to power said first and second annular inductors so that said first heating zone and said second heating zone only partially overlap on said annular wall to generate a gradient of temperatures along the height of said annular wall; a conveyor configured to receive and convey mineral fibers, a first blowing ring configured to blow air on the mineral fibers that are about to leave through the plurality of orifices in the annular wall so as to drive them to the conveyor, wherein the mineral fiber forming device is devoid of any burner located externally to said centrifuge. 2. The mineral fiber forming device of claim 1 , wherein the first and second annular inductors are arranged in series and powered by a same power generator. 3. The mineral fiber forming device of claim 2 , wherein the gradient of temperatures is generated based on a position, a number and a diameter of turns of each of the first and second annular inductors. 4. The mineral fiber forming device of claim 1 , wherein the first and second annular inductors are arranged in parallel and powered by two independent power generators, said two independent power generators adapted to supply power independently to said first and second annular inductors to generate the gradient of temperatures. 5. The mineral fiber forming device of claim 1 , wherein the gradient of temperatures is generated to control a viscosity of the glass along the height of the annular wall and generate glass fibers that have uniform dimensions and properties. 6. The mineral fiber forming device of claim 1 , wherein the first and second annular inductors each include a field concentrator to direct a respective electromagnetic field generated by the first and second annular inductors towards said centrifuge to generate said first and second heating zones. 7. The mineral fiber forming device of claim 1 , further comprising a second blowing ring configured to blow air, the cooperation of the first and second blowing rings creating an area of turbulences in proximity to the annular wall of the centrifuge, said area of turbulences allowing for an additional drawing of the mineral fibers that are about to leave through the plurality of orifices in the annular wall. 8. The mineral fiber forming device of claim 1 , further comprising an internal burner that is adapted for use on starting up the mineral fiber forming device. 9. The mineral fiber forming device of claim 1 , wherein a position, a number and a diameter of turns of each of the first and second annular inductors are set to achieve said only partial overlap of said first heating zone and said second heating zone on said annular wall during drawing of the mineral fibers through the plurality of orifices. 10. The mineral fiber forming device of claim 1 , wherein the centrifuge includes a solid bottom that extends from the annular axis of the centrifuge to the annular wall so as to close a lower part of the centrifuge and receive the molten glass from the hollow shaft. 11. The mineral fiber forming device of claim 10 , wherein the second inductor is positioned to heat the solid bottom of the centrifuge.