Element for ejecting gas into a regenerator of a fluid catalytic cracking unit

The invention claimed is: 1. An injection element for a gas injection system inside a regenerator of a fluid catalytic cracking unit, the gas injection system comprising a support defining at least one orifice, this support comprising a wall defining at least one portion of a cavity and having a first face intended to be in contact with the gas contained in this cavity, and the support comprising a second face, opposite the first face, intended to be in contact with a fluidized catalyst bed, wherein the injection element comprises a flow passage and is arranged so as to be able to be firmly attached to the support, at the orifice, so that gas from the cavity can circulate via the flow passage to the fluidized catalyst bed, characterized in that the injection element is made of a ceramic material comprising a ceramic matrix and carbon and/or ceramic fibres incorporated into this ceramic matrix, wherein the ceramic material comprises silicon carbide in a majority amount. 2. The injection element according to claim 1 , in which the ceramic material is a Ceramic Matrix Composite (CMC). 3. A gas injection system for injecting gas into a regenerator of a fluid catalytic cracking unit, the gas injection system comprising: at least one injection element, and a support defining at least one orifice, this support comprising a wall defining at least one portion of a cavity and having a first face intended to be in contact with the gas contained in this cavity, and the support comprising a second face, opposite the first face, intended to be in contact with a fluidized catalyst bed, in which the injection element defines a flow passage and is arranged so as to be able to be firmly attached to the support, at the orifice, so that gas from the cavity can circulate via the flow passage to the fluidized catalyst bed, characterized in that the injection element is made of a ceramic material comprising a ceramic matrix and carbon and/or ceramic fibres incorporated into this ceramic matrix, wherein the ceramic material comprises silicon carbide in a majority amount. 4. The gas injection system according to claim 3 , in which, for at least one injection element, the injection system comprises a device for fastening the injection element to the support, the fastening device being capable of absorbing a difference in expansion between the material of the support and the ceramic material of the injection element. 5. The gas injection system according to claim 4 , in which, for at least one injection element, the fastening device comprises at least one pressing element capable of exerting a force on this injection element in order to press this injection element against the support. 6. The gas injection system according to claim 5 , in which the pressing element comprises a tab welded via one end to the support and of which the other end is capable of exerting an elastic bearing force on the injection element when the injection element is installed on the support. 7. The gas injection system according to claim 3 , in which the support comprises a perforated plate arranged to cover the whole of a cross section of a chamber of the regenerator in order to support the fluidized catalyst bed. 8. The gas injection system according to claim 3 , wherein the ceramic material comprises silicon carbide SiC, preferably in a majority amount. 9. The gas injection system according to claim 3 , wherein the ceramic material is a Ceramic Matrix Composite (CMC). 10. A process for manufacturing a gas injection element for a regenerator of a fluid catalytic cracking unit, so that this element defines a flow passage for the gas, intended to open on one side into a cavity and on the other side into a fluidized bed, the process being characterized in that the injection element is made of ceramic material comprising a ceramic matrix and carbon and/or ceramic fibres incorporated into this ceramic matrix, wherein the process comprises: 1) shaping a fibrous ceramic material over a supporting material that could be removed without excessive effort, in order to obtain a fibrous shape that can be assimilated to the backbone of the final device to be obtained, in the presence of a first resin, 2) coating the shape obtained at step (1) with finely divided ceramic powder and at least a second resin, in the presence of finely divided carbon powder, to obtain a coated shape, 3) repeat steps (1) and (2), 4) heating the coated shape of step (2) or (3) under vacuum and/or under inert atmosphere in order to transform the resins of step (1), (2) and (3) into a carbon-rich structure, essentially deprived of other elements to obtain a carbon-rich coated shape, 5) introducing a gas within the carbon-rich coated shape of step (4) under conditions efficient to transform the carbon-rich structure into carbide containing carbon-rich structure, 6) removing the supporting material of step (1), when present, wherein carbon fibers are present at least at step (1), (2) and/or (3) within the fibrous ceramic material, within the finely divided ceramic powder, within the finely divided carbon powder, and/or within the first and/or second resin. 11. The manufacturing process according to claim 10 , comprising a step of sintering silicon carbide SiC particles.