Method of fabricating a turbine or compressor guide vane sector made of composite material for a turbine engine, and a turbine or a compressor incorporating such guide vane sectors

The invention claimed is: 1. A method of fabricating a turbine nozzle or a compressor diffuser for a turbine engine, the method comprising: a) making a plurality of single-airfoil vane units, each vane having inner and outer platforms and an airfoil extending between the platforms and connected thereto, and being made by: forming a fiber blank by three-dimensional weaving, the blank being in the form of a strip and comprising a first segment with second and third segments extending the first segment at respective first and second longitudinal ends thereof, each of the second and third segments being split into two portions on either side of a zone of non-interlinking extending within the thickness and across the entire width of the strip; forming a fiber preform for the vane to be made by laterally deploying the two portions of the second segment and the two portions of the third segment and shaping said portions so as to obtain inner and outer platform preforms, and by shaping the first segment so as to obtain an airfoil preform; and at least partially densifying the fiber preform with a matrix in order to obtain and at least partially densified vane with inner and outer platforms incorporated therein; and b) assembling and bonding together a plurality of at least partially densified vanes: the bonding being performed by a process comprising at least one step selected from: a step of bonding by brazing and a step of bonding by co-densification; and the inner or outer platform of a first vane comprising respectively an inner or outer passage-constituting platform portion that is bonded to respectively an inner or outer platform portion of an adjacent second vane in a bonding zone extending respectively over at least a portion of an inside surface of the inner passage-constituting platform portion of the first vane or over at least a portion of an inner surface of the outer passage-constituting platform portion of the first vane. 2. A method according to claim 1 , wherein: single-airfoil vanes are assembled together, each having at respectively its outer or inner platform and on either side of the airfoil, a single single-function platform portion; and at respectively the outer or inner platform, a single platform portion situated on a first side of the airfoil is engaged on the inside or the outside of a single platform portion situated on a second side of a second vane adjacent to the first vane. 3. A method according to claim 1 , wherein the making of each vane includes the step of partially densifying the fiber preform with a matrix, followed by a step of machining. 4. A method according to claim 3 , wherein the plurality of partially densified machined vanes are assembled and bonded together by co-densification. 5. A method according to claim 4 , for making a nozzle or diffuser sector out of ceramic matrix composite material, wherein assembling together the partially densified machined vanes includes a step of pre-ceramic adhesive bonding. 6. A method according to claim 3 , for making a nozzle or diffuser sector out of ceramic matrix composite material, wherein the making of each vane includes first and second steps of densification by means of a ceramic matrix, which steps are separated by a step of machining, and the bonding together of a plurality of vanes includes the step of brazing assembled-together vanes after the second densification step. 7. A method according to claim 1 , wherein one of the two portions of the third segment of the fiber strip is deployed and shaped in order to form a preform for an outer passage-constituting platform portion on one side of the airfoil preform and the other portion of the third segment of the fiber strip is deployed and shaped in order to form a preform for a portion of a set of attachment tabs on the other side of the airfoil preform, the preforms for the outer passage-constituting platform portion and for the set of attachment tabs being attached to the airfoil preform at positions that are mutually offset in the longitudinal direction, such that when two adjacent vanes are assembled together a portion of the outer passage-constituting platform portion of one of the two vanes engages the inside of a portion of the set of attachment tabs of the other one of the two vanes. 8. A method according to claim 1 , wherein one of the two portions of the second fiber strip segment is deployed and shaped in order to form a preform for an inner passage-constituting platform portion on one side of the airfoil preform, and the other portion of the second fiber strip segment is deployed and shaped in order to form a preform for a portion of a set of hooks on the other side of the vane preform, the preforms for the inner passage-constituting platform portions and for the set of hooks being connected to the airfoil preform at positions that are mutually offset in the longitudinal direction in such a manner that when assembling two adjacent vanes together, an inner passage-constituting platform portion of one of the two vanes engages on the outside of the portion of a set of hooks of the other one of the two vanes. 9. A method according claim 1 , including assembling and bonding together first single-airfoil vanes alternating with second single-airfoil vanes, and: the making of each first vane comprises deploying and shaping the two portions of the third fiber strip segment in order to form a preform for an outer passage-constituting platform portion on either side of the airfoil preform; and the making of each second vane comprises deploying and shaping the two portions of the third fiber strip segment to form a preform for a set of attachment tabs portion on either side of the airfoil preform; an outer passage-constituting platform portion of each first vane being engaged on the inside of the set of attachment tabs portion of each second vane during assembly of the vane. 10. A method according to claim 1 , including assembly and bonding together first single-airfoil vanes in alternation with second single-airfoil vanes, and: the making of each first vane comprises deploying and shaping the two portions of the second fiber strip segment to form a preform for an inner passage-constituting platform portion on either side of the airfoil preform; and the making of each second vane comprises deploying and shaping the two portions of the second fiber strip segment to form a preform for a set of hooks portion on either side of the airfoil preform; an inner passage-constituting platform portion of each first vane being engaged on the outside of the set of hooks portion of each second vane when assembling the vanes together. 11. A method according to claim 1 , wherein the first segment of the fiber blank is woven while leaving an internal zone of non-interlinking that extends over the entire longitudinal dimension of the first segment and that communicates at its ends with the zones of non-interlinking in the second segment and in the third segment, and the shaping of the first segment includes forming a passage along the zone of non-interlinking in the first segment in order to obtain a hollow airfoil preform. 12. A turbine engine turbine having a turbine casing and at least one turbine nozzle made of ceramic composite material having nozzle sectors fabricated by the method according to claim 1 . 13. A turbine according to claim 12 , wherein the nozzle has nozzle sectors and is mounted in the turbine casing by means of attachment tabs, wherein one of the two portions of the third segment of the fiber strip is deployed and shaped in order to form a preform for an outer passage-constituting platform portion on o