Process for making a container of a given shape from sheet material

The invention claimed is: 1 . A process for obtaining a container ( 100 ) of a given shape from sheet material, comprising the steps of: providing a sheet ( 110 ); providing a mould ( 20 ) having a forming cavity ( 20 A), which defines a reference axis (R) and has a shape corresponding to said given shape of said container ( 100 ); positioning said sheet ( 110 ) over said forming cavity ( 20 A); providing a forming device ( 40 ) having a forming member ( 41 , 42 ) arranged on the side of said sheet opposite to said forming cavity, and inserting said sheet ( 110 ) into said forming cavity ( 20 A) by said forming member to deform it until a container blank is obtained ( 101 ) having a shape approximating said given shape; and blowing a gas under pressure into said forming cavity ( 20 A) to deform said container blank ( 101 ) until said container ( 100 ) with said given shape is obtained; said process being characterized in that said step of inserting said sheet ( 110 ) into said forming cavity includes: setting in contact with said sheet a first operating surface (S 1 ) of the forming member ( 41 , 42 ) and pushing through said first operating surface (S 1 ) said sheet ( 110 ) into said forming cavity ( 20 A), for a first stretch (H 1 ) along said reference axis (R), wherein said sheet is deformed as a result of said pushing through said first operating surface (S 1 ) said sheet ( 110 ) into said forming cavity ( 20 A), for a first stretch (H 1 ) along said reference axis (R); and further pushing said sheet ( 110 ) into said forming cavity ( 20 A) by way of a second operating surface (S 2 ) of the forming member ( 41 , 42 ), which is of smaller size than said first surface (S 1 ), for a second stretch (H 2 ) along said reference axis (R), wherein said sheet is further deformed as a result of said further pushing said sheet ( 110 ) into said forming cavity ( 20 A) by way of a second operating surface (S 2 ) of the forming member ( 41 , 42 ), which is of smaller size than said first surface (S 1 ), for a second stretch (H 2 ) along said reference axis (R); providing, through said first operating surface (S 1 ), a first portion ( 101 A) of said container blank ( 101 ), which extends along said first stretch (H 1 ) and has a cross section determined by said first operating surface (S 1 ); and providing, through said second operating surface (S 2 ), a second portion ( 101 B) of said container blank ( 101 ), which extends along said second stretch (H 2 ) and has a cross section determined by said second operating surface (S 2 ), wherein the section transverse to said reference axis (R) of said first portion ( 101 A) is of larger size than the cross section of said second portion ( 101 B), and wherein a first region of the second portion has substantially constant cross section, and a second region of the second portion has a cross section that decreases downward. 2 . The process according to claim 1 , wherein said forming member comprises a first forming member ( 41 ) and a second forming member ( 42 ) that can be driven along said reference axis (R) separately or simultaneously, said process including: setting said first and second forming members ( 41 , 42 ) substantially in one and the same position along said reference axis (R) so that they define together said first operating surface (S 1 ); in this condition, feeding said first and second forming members ( 41 , 42 ) in a fixed way with respect to one another along said reference axis (R), for said first stretch (H 1 ); and keeping said first forming member ( 42 ) stationary and further feeding said second forming member ( 41 ) along said reference axis (R), for said second stretch (H 2 ), one end ( 41 A) of said second member defining said second operating surface (S 2 ). 3 . The process according to claim 2 , which includes blowing gas into said forming cavity ( 20 A) in a condition where said first forming member ( 42 ) is positioned at the end of said first stretch (H 1 ), and said second forming member ( 41 ) is positioned at the end of said second stretch (H 2 ); and/or blowing gas into said forming cavity ( 20 A) during movement of said first and second forming members ( 42 , 41 ) along said first stretch (H 1 ); and/or blowing gas into said forming cavity ( 20 A) during movement of said second forming member ( 41 ) along said second stretch (H 2 ). 4 . The process according to claim 2 , wherein said forming device ( 40 ) comprises a thermal-conditioning system to keep said first forming members ( 41 ) and/or said second forming member ( 42 ) at a pre-set temperature. 5 . The process according to claim 1 , wherein, in said forming device ( 40 ): said first and second forming members ( 41 , 42 ) are mounted inside one another in a telescopic way; and said first forming member ( 42 ) has a tubular conformation, and said second forming member ( 41 ) has a cylindrical conformation, said first and second members ( 41 , 42 ) presenting the corresponding axes aligned with said reference axis; said process including: setting corresponding ends ( 41 A, 42 A), facing said mould cavity ( 20 A), of said first and second forming members ( 41 , 42 ) substantially in one and the same position along said reference axis (R) to form said first operating surface (S 1 ), in said condition, feeding said first and second forming members ( 41 , 42 ) along said reference axis (R) in a fixed way with respect to one another, for said first stretch (H 1 ); and keeping said first forming member ( 42 ) stationary, and feeding said second forming member ( 41 ) further along said reference axis (R), for said second stretch (H 2 ), getting said second forming member ( 41 ) to project from said first forming member ( 42 ). 6 . The process according to claim 1 , wherein along said reference axis (R) a given height of said container ( 100 ) is determined, subtended between its mouth edge ( 100 ′) and its bottom, and wherein, on said container ( 100 ), along said reference axis (R), a first portion ( 100 A) and a second portion ( 100 B) distinct from one another are determined, said first portion ( 100 A) presenting a section transverse to said reference axis (R) of larger size than the cross section of said second portion ( 100 B). 7 . The process according to claim 1 , wherein said sheet may be made of thermoformable or deformable material. 8 . The process according to claim 7 , wherein said sheet may be made of one or more of plastic resins, paper, polymeric material, and aluminium. 9 . The process according to claim 1 , wherein said sheet is heated prior to said forming steps. 10 . A process for obtaining a container ( 100 ) of a given shape from sheet material, comprising the steps of: providing a sheet ( 110 ); providing a mould ( 20 ) having a forming cavity ( 20 A), which defines a reference axis (R) and has a shape corresponding to said given shape of said container ( 100 ); positioning said sheet ( 110 ) over said forming cavity ( 20 A); providing a forming device ( 40 ) having a first forming member ( 41 ) and a second forming member ( 42 ) arranged on the side of said sheet opposite to said forming cavity, and operating said first and second forming members for inserting said sheet ( 110 ) into said forming cavity ( 20 A) to deform it until a container blank is obtained ( 101 ) having a shape approximating said given shape; and blowing a gas under pressure into said forming cavity ( 20 A) to deform said container blank ( 101 ) until said container ( 100 ) with said given shape is obtained; said process being characterized in that said step of inserting said sheet ( 110 ) into said forming cavity includes: gripping said shee