Double-acting pressure reducing cylinder with adaptive support

The invention claimed is: 1. Double-acting pressure reducing cylinder ( 1 ) with adaptive support comprising a cylinder shaft ( 71 ), cooperating with a double-acting pressure reducing piston ( 2 ) which is connected by a lower piston rod ( 46 ) to means of transmission ( 3 ) installed in a transmission casing ( 8 ) to which the cylinder shaft ( 71 ) is secured, while the end of said shaft ( 71 ) which emerges from the side of said means ( 3 ) is closed by a lower cylinder head ( 9 ) through which the lower piston rod ( 46 ) passes via a lower rod opening ( 51 ) to define with the double-acting pressure reducing piston ( 2 ) a lower chamber of hot gases ( 11 ), while the other end of said shaft ( 71 ) is closed by an upper cylinder head ( 10 ) to define with said piston ( 2 ) an upper chamber of hot gases ( 12 ), wherein the double-acting pressure reducing cylinder comprises: at least one hollow pillar ( 13 ) through which passes entirely in the direction of its length a rod tunnel ( 14 ), a first pillar end ( 15 ) of said pillar ( 13 ) resting directly or indirectly on the transmission casing ( 8 ), while a second pillar end ( 16 ) of said pillar ( 13 ) directly or indirectly supports the cylinder shaft ( 71 ), the lower cylinder head ( 9 ) and the upper cylinder head ( 10 ), while said first end ( 15 ) can pivot about a ball joint ( 42 ) and/or bend in relation to said casing ( 8 ), while said second end ( 16 ) can pivot about said ball joint ( 42 ) and/or bend in relation to said cylinder shaft ( 71 ); at least one tie rod ( 17 ), installed in the rod tunnel ( 14 ), a first rod end ( 18 ) of said tie rod ( 17 ) being directly or indirectly secured to the transmission casing ( 8 ), while a second rod end ( 19 ) of said tie rod ( 17 ) is secured to the cylinder shaft ( 71 ) and/or to the lower cylinder head ( 9 ) and/or to the upper cylinder head ( 10 ), said first end ( 18 ) being able to pivot about said ball joint ( 42 ) and/or bend in relation to said casing ( 8 ), while said second end ( 19 ) can pivot about said ball joint ( 42 ) and/or bend in relation to said cylinder ( 1 ); lower cylinder centering means ( 20 ) positioned near the lower cylinder head ( 9 ), said means ( 20 ) bearing against the cylinder shaft ( 71 ) or the lower cylinder head ( 9 ), on the one hand, and directly or indirectly against the transmission casing ( 8 ) on the other hand, and said means ( 20 ) leaving the cylinder shaft ( 71 ) free to move in parallel with its longitudinal axis in relation to the transmission casing ( 8 ), yet preventing said shaft ( 71 ) from moving in the plane perpendicular to said axis, again with respect to said casing ( 8 ); upper cylinder centering means ( 21 ) positioned near the upper cylinder head ( 10 ), said means ( 21 ) bearing against the cylinder shaft ( 71 ) or the upper cylinder head ( 10 ), on the one hand, and against a centering frame ( 22 ) rigidly fixed to the transmission casing ( 8 ) and maintained at a height near that of the upper cylinder head ( 10 ) by at least one rigid frame pillar ( 23 ), on the other hand, said means ( 21 ) leaving the cylinder shaft ( 71 ) free to move in parallel with its longitudinal axis in relation to the transmission casing ( 8 ), yet preventing said shaft ( 71 ) from moving in the plane perpendicular to said axis, again with respect to said casing ( 8 ). 2. Double-acting pressure reducing cylinder according to claim 1 , further comprising at least one rod cooling tube ( 30 ) which tightly surrounds the tie rod ( 17 ) for all or part of the length of said rod ( 17 ), a cooling fluid ( 31 ) coming from a source of cooling fluid ( 40 ) being able to circulate in a space left free between the internal wall of said tube ( 30 ) and the outer surface of said rod ( 17 ), while the largest possible portion of the outer surface of said tube ( 30 ) does not touch the internal wall of the rod tunnel ( 14 ) so as to define with the latter wall an empty space. 3. Double-acting pressure reducing cylinder according to claim 2 , further comprising at least one first tube feed opening ( 32 ) which communicates with the interior of the rod cooling tube ( 30 ) in the vicinity of the first rod end ( 18 ), and/or at least one second tube feed opening ( 33 ) which communicates with the interior of the rod cooling tube ( 30 ) in the vicinity of the second rod end ( 19 ), the cooling fluid ( 31 ) being able to circulate between the two said openings ( 32 , 33 ). 4. Double-acting pressure reducing cylinder according to claim 2 , wherein the rod cooling tube ( 30 ) has a tube collar ( 34 ) held directly or indirectly clamped by the tie rod ( 17 ) either against a fixation lug ( 25 ) on the cylinder shaft ( 71 ) or the upper cylinder head ( 10 ), or against the transmission casing ( 8 ). 5. Double-acting pressure reducing cylinder according to claim 4 , wherein the tube collar ( 34 ) is held clamped by the tie rod ( 17 ) against the fixation lug ( 25 ) by means of a Banjo fitting ( 38 ), which has at least one radial connection conduit ( 39 ) connected to the source of cooling fluid ( 40 ) on the one hand, and communicating with the interior of the rod cooling tube ( 30 ) on the other hand. 6. Double-acting pressure reducing cylinder according to claim 4 , wherein a thermal insulation spacer which ( 68 ) is inserted between the tube collar ( 34 ) and the fixation lug ( 25 ), said spacer ( 68 ) being traversed from one end to the other in the direction of its length by a spacer tunnel ( 69 ) in which is installed the tie rod ( 17 ) and the rod cooling tube ( 30 ) which surrounds it in tight manner, while the largest possible portion of the outer surface of said tube ( 30 ) does not touch the internal wall of the spacer tunnel ( 69 ) so as to define with the latter wall an empty space. 7. Double-acting pressure reducing cylinder according to claim 2 , wherein the rod cooling tube ( 30 ) has at least one tube bulge ( 35 ) constituted by an axial portion of said tube ( 30 ) whose diameter is essentially equivalent to or slightly greater than that of the rod tunnel ( 14 ) in which it is installed. 8. Double-acting pressure reducing cylinder according to claim 2 , wherein the rod cooling tube ( 30 ) has at least one constriction of tube diameter ( 36 ) constituted by an axial portion of said tube ( 30 ) whose diameter is essentially equivalent to or slightly less than that of the body of the tie rod ( 17 ). 9. Double-acting pressure reducing cylinder according to claim 2 , wherein the rod cooling tube ( 30 ) has at least one radial communication hole ( 37 ) which allows the cooling fluid ( 31 ) to enter said tube ( 30 ), or to exit from it. 10. Double-acting pressure reducing cylinder according to claim 1 , wherein the tie rod ( 17 ) is hollow to form an internal rod cooling channel disposed in the length of said rod ( 17 ), said channel emerging axially or radially from said rod ( 17 ), while a cooling fluid ( 31 ) coming from a source of cooling fluid ( 40 ) can circulate in said channel ( 41 ). 11. Double-acting pressure reducing cylinder according to claim 1 , wherein a pressure chamber ( 44 ) connected to a source of pressurized air ( 45 ) is secured to the centering frame ( 22 ) or disposed on or in the latter, while an upper piston rod ( 47 ) which prolongs the double-acting pressure reducing piston ( 2 ) on the side of the upper chamber of hot gases ( 12 ) passes through the upper cylinder head ( 10 ) via an upper rod opening ( 43 ) disposed in said cylinder head ( 10 ) and via an access opening to the chamber ( 52 ) passing through the centering frame ( 22 ) to emerge in the pressure chamber ( 44 ) such that the end of said rod ( 47 ) which is furthest away from said piston ( 2 ) alway