Method for manufacturing ophthalmic lenses by machining

The invention claimed is: 1. A process for manufacturing by machining an ophthalmic lens ( 1 ) having a first face ( 2 ) and a second face ( 3 ) opposite said first face ( 2 ), said first face ( 2 ) being provided with a first optical area ( 4 ) and said second face ( 3 ) being provided with a second optical area ( 5 ), said first and second optical areas ( 4 , 5 ) defining an optically useful zone ( 6 ) of said ophthalmic lens ( 1 ), said process comprising steps of: providing ( 70 ) a lens blank ( 10 ) having an upper face ( 12 ), and a lower face ( 13 ) opposite said upper face ( 12 ) and a peripheral edge face ( 17 ) joining said upper and lower faces ( 12 , 13 ); providing ( 71 ) a first holding device ( 30 ; 130 ) having a first machining frame of reference ( 18 ) defined by three translational directions corresponding to three axes of a basic orthonormal coordinate system and by three rotational directions defined about said three translational directions, respectively, with two of said three translational directions being located in one and the same first plane and the other of said three translational directions being located in a second plane; said process being characterized in that it comprises steps of: mounting ( 72 ) said lens blank ( 10 ) on said first holding device ( 30 ; 130 ) in a first position in which said lower face ( 13 ) of said lens blank ( 10 ) is facing said first holding device ( 30 ; 130 ), which is configured to hold said lens blank ( 10 ) via its lower face ( 3 ) or via its peripheral edge face ( 17 ); machining ( 73 ; 74 ; 77 ; 78 ; 81 ), in said first position in said first machining frame of reference ( 18 ), said upper face ( 12 ) to obtain said first optical area ( 4 ) and thus form a semi-finished lens blank ( 8 ); machining ( 73 ; 75 ; 76 ; 79 ; 80 ), in a second machining frame of reference ( 19 ) defined in the same way as said first machining frame of reference ( 18 ), at least one mechanical referencing element ( 42 ; 45 ; 47 ) in at least any one of said upper and lower faces ( 12 , 13 ) and said peripheral edge face ( 17 ), said second machining frame of reference ( 19 ) being preset and known relative to said first machining frame of reference ( 18 ), and said machining step ( 73 ; 75 ; 76 ; 79 ; 80 ) being configured so that said at least one mechanical referencing element ( 42 ; 45 ) is located outside of said optically useful zone ( 6 ), so as thus to form a referenced semi-finished lens blank ( 9 ); and providing ( 84 ) a second holding device ( 150 ) comprising at least one complementary mechanical referencing element ( 159 , 161 ), which is configured to interact with said at least one mechanical referencing element ( 42 ; 45 ) of said referenced semi-finished lens blank ( 9 ) so that the latter is positioned and held on said second holding device ( 150 ) in a second position that is preset at least in said three translational directions and in said two rotational directions defined about said two translational directions that are located in said first plane, respectively, said at least one mechanical referencing element being formed by machining at least one chamfered zone ( 42 ; 45 ) produced at least in said peripheral edge face ( 17 ) and in either one of said upper and lower faces ( 12 , 13 ), outside of said optically useful zone ( 6 ), and said at least one complementary mechanical referencing element being formed by at least one shoulder ( 160 , 161 ) produced in said second holding device ( 150 ) and configured to receive in abutment said at least one chamfered zone. 2. The process as claimed in claim 1 , wherein said first machining frame of reference ( 18 ) and said second machining frame of reference ( 19 ) are coincident. 3. The process as claimed in claim 1 , wherein said steps ( 73 ; 74 ; 77 ) of machining said upper face ( 12 ) and said at least one mechanical referencing element ( 42 ; 45 ) are successive or merged. 4. The process as claimed in claim 1 , wherein said first machining frame of reference ( 18 ) and said second machining frame of reference ( 19 ) are separate, said second machining frame of reference having a known offset relative to said first machining frame of reference. 5. The process as claimed in claim 1 , wherein at least one other of said mechanical referencing elements is formed by machining at least one grooved zone ( 40 ) produced in said peripheral edge face ( 17 ) or in either one of said upper and lower faces ( 12 , 13 ), outside of said optically useful zone ( 6 ); and at least one other of said complementary mechanical referencing elements is formed by at least one protuberance ( 53 ) produced in said second holding device ( 50 ) and configured to be received in abutment in said at least one grooved zone ( 40 ). 6. The process as claimed in claim 1 , wherein said at least one chamfered zone ( 45 ) is at least partially continuous and of constant size, of constant width or depth, respectively, and said at least one mechanical referencing element is furthermore formed by machining a blocking zone ( 46 ) on said peripheral edge face ( 17 ), which blocking zone ( 46 ) is configured to position said referenced semi-finished lens blank ( 9 ) in said rotational direction defined about said translational direction that is located in said second plane. 7. The process as claimed in claim 1 , wherein said at least one chamfered zone ( 42 ) is at least partially continuous and of variable size, of variable width or depth, respectively. 8. The process as claimed in claim 1 , wherein at least one other of said mechanical referencing elements is formed by machining a plurality of individual indents ( 47 ) produced in said peripheral edge face ( 17 ) and/or in either one of said upper and lower faces ( 12 , 13 ), outside of said optically useful zone ( 6 ); and at least one other of said complementary mechanical referencing elements is formed by a plurality of protuberances produced in said second holding device and configured to receive in abutment said plurality of individual indents. 9. The process as claimed in claim 1 , further comprising steps of: mounting ( 85 ) said referenced semi-finished lens blank ( 9 ) on said second holding device ( 150 ) in said second preset position, said device ( 50 ; 150 ) being configured to hold said referenced semi-finished lens blank ( 9 ) via its upper face ( 12 ) or via its peripheral edge face ( 17 ); and machining ( 86 ) said lower face ( 13 ) of said referenced semi-finished lens blank ( 9 ) to obtain said second optical area ( 5 ) and thus form said ophthalmic lens ( 1 ). 10. The process as claimed in claim 1 , wherein said at least one chamfered zone ( 42 , 45 ) of said lens blank ( 9 ) has an angle of inclination (α 1 , α 2 , α 3 ) relative to said edge face ( 7 ) of said lens blank ( 9 ), which angle of inclination is set so as to increase contact between said lens blank ( 9 ) and said second holding device ( 150 ) depending on at least one preset constraint. 11. The process as claimed in claim 10 , wherein said angle of inclination (α 1 , α 2 , α 3 ) of said at least one chamfered zone ( 42 , 45 ) is set depending on a characteristic representative of a perimeter of contact between said at least one chamfered zone ( 42 , 45 ) of said lens blank ( 9 ) and said complementary mechanical referencing element ( 159 , 161 ) of said second holding device ( 50 ; 150 ) in order to ensure the stability of said lens blank ( 9 ) in said second holding device ( 150 ). 12. The process as claimed in claim 10 , wherein said angle of inclination (α 1 , α 2 , α 3 ) of said at least one chamfered zone ( 42 , 45 ) is set depending o