Drain for dynamic sealing assembly

The invention claimed is: 1. A system comprising: a shaft ( 1 ) presenting a distal end ( 11 ) and a proximal end, a casing (C) defining a housing under a casing pressure in which a hydraulic device (M) is rotatably mounted on the shaft ( 1 ), said hydraulic device being a hydraulic motor (M) comprising a multilobe cam ( 61 ) fixed to the casing, a cylinder block ( 6 ) placed on the shaft ( 1 ) opposite the cam ( 61 ), pistons guided to slide radially in respective cylinders of the cylinder block ( 6 ) and supported on the lobes of the cam ( 61 ), and a distributor ( 71 , 72 ) intended to successively apply pressurised fluid to the pistons, arranged at the distal end of the shaft ( 1 ), a sealing member forming dynamic sealing between the shaft and the housing defined by the casing comprising low-pressure dynamic sealing means ( 4 ) around the shaft and reinforced dynamic sealing means ( 5 ) formed from a static sealing gasket ( 51 ) tightly mounted on a friction pad ( 51 ) between the low-pressure dynamic sealing means ( 4 ) and the hydraulic motor so as to isolate said dynamic sealing means ( 4 ) from the rotating hydraulic motor (M), and defining a discharge chamber between the dynamic sealing means ( 4 ) and the reinforced dynamic sealing means ( 5 ), wherein the system further comprises a first drain fluidly isolated from the casing and connected to an atmospheric pressure tank, and the discharge chamber is connected to the first drain ( 18 ) via a pipe ( 16 ) arranged on the surface of the shaft ( 1 ) between the hydraulic motor (M) and the shaft and a channel ( 17 ) arranged at the distal end ( 11 ) of the shaft ( 1 ) so as to create a fluidic connection between said pipe ( 16 ) arranged between the hydraulic motor (M) and the shaft ( 1 ) and a first axial pipe ( 18 ) arranged in the shaft ( 1 ) so as to discharge fluid located in the discharge chamber to the atmospheric pressure tank such that said discharge chamber is not subjected to the pressure prevailing in the casing (C) of the hydraulic device (M), the system further comprising means for fluidic connection between a second axial pipe ( 25 ) arranged in the shaft ( 1 ), terminating at the distal end of the shaft, and the casing (C), so as to form a second drain allowing regulation of the casing pressure (C) and allowing to control the casing pressure to manoeuvre the hydraulic motor, said first drain allowing to evacuate the fluid which accumulates in the discharge chamber during pressure points in the casing of the hydraulic motor and thus to discharge the leaks of the hydraulic motor. 2. The system according to claim 1 , in which said pipe ( 16 ) arranged between the hydraulic motor (M, F) and the shaft ( 1 ) is a groove made at the periphery of the shaft ( 1 ), from its distal end ( 11 ) to the discharge chamber. 3. The system according to claim 1 , in which said sealing member comprises a friction surface ( 2 ) tightly mounted on the shaft ( 1 ), on which is mounted the low-pressure dynamic sealing means ( 4 ), said friction surface ( 2 ) comprising a bore ( 22 , 23 ) terminating on the pipe ( 16 ) arranged on the surface of the shaft ( 1 ) so as to connect the discharge chamber to said pipe ( 16 ). 4. The system according to claim 1 , wherein said sealing member comprises a friction surface ( 2 ) tightly mounted on the shaft ( 1 ), on which is mounted the low-pressure dynamic sealing means ( 4 ), said friction surface ( 2 ) comprising a bore ( 22 , 23 ) terminating on the pipe ( 16 ) arranged on the surface of the shaft ( 1 ) so as to connect the discharge chamber to said pipe ( 16 ); and in which said channel ( 17 ) at the distal end of the shaft ( 1 ) is arranged in the shaft ( 1 ). 5. The system of claim 1 , in which an axial pipe traversing ( 27 ) is arranged in the distributor ( 72 ) so as to create the fluidic connection between the second axial pipe arranged in the shaft ( 25 ) and the casing ( 1 ), independently of said first drain ( 18 ) connected to the discharge chamber. 6. The system according to claim 1 , wherein said sealing member comprises a friction surface ( 2 ) tightly mounted on the shaft ( 1 ), on which is mounted the low-pressure dynamic sealing means ( 4 ), said friction surface ( 2 ) comprising a bore ( 22 , 23 ) terminating on the pipe ( 16 ) arranged on the surface of the shaft ( 1 ) so as to connect the discharge chamber to said pipe ( 16 ); and in which said channel ( 17 ) at the distal end of the shaft ( 1 ) is arranged in the distributor ( 72 ). 7. A system comprising: a shaft ( 1 ) presenting a distal end ( 11 ) and a proximal end, a casing (C) defining a housing under a casing pressure in which a hydraulic device (F) is rotatably mounted on the shaft ( 1 ), said hydraulic device being a multidisc brake (F), comprising a plurality of discs ( 81 ) mounted on a splined sleeve ( 8 ) fixed relative to the shaft ( 1 ), a plurality of complementary discs ( 82 ) mounted non-rotatably relative to the casing (C), control means ( 83 , 84 , 85 ) of the discs ( 81 , 82 ) adapted to control their contacting, a sealing member forming dynamic sealing between the shaft and the housing defined by the casing comprising low-pressure dynamic sealing means ( 4 ) around the shaft and reinforced dynamic sealing means ( 5 ) formed from a static sealing gasket ( 51 ) tightly mounted on a friction pad ( 51 ) between the low-pressure dynamic sealing means ( 4 ) and the hydraulic multidisc brake so as to isolate said dynamic sealing means ( 4 ) from the rotating hydraulic multidisc brake (F), and defining a discharge chamber between the dynamic sealing means ( 4 ) and the reinforced dynamic sealing means ( 5 ), wherein the system further comprises a first drain fluidly isolated from the casing of the rotating hydraulic multidisc brake and connected to an atmospheric pressure tank, and the discharge chamber is connected to the first drain ( 18 ) via a pipe ( 16 ) arranged on the surface of the shaft ( 1 ) between the hydraulic multidisc brake (F) and the shaft and a channel ( 17 ) arranged at the distal end ( 11 ) of the shaft ( 1 ) so as to discharge fluid located in the discharge chamber to the atmospheric pressure tank such that said discharge chamber is not subjected to the pressure prevailing in the casing (C) of the hydraulic multidisc brake (F), and further comprises a second drain allowing regulation of the casing pressure (C) of the hydraulic multidisc brake and allowing to control the casing pressure to manoeuvre the hydraulic multidisc brake, said first drain allowing to evacuate the fluid which accumulates in the discharge chamber during pressure points in the casing of the hydraulic multidisc brake and thus to discharge the leaks of the hydraulic multidisc brake, in which said pipe arranged between the hydraulic multidisc brake and the shaft is a groove ( 16 ) made at the periphery of the shaft ( 1 ) between the shaft ( 1 ) and the splined sleeve ( 8 ), from the distal end ( 11 ) of the shaft ( 1 ) to the discharge chamber. 8. The system according to claim 7 , in which said pipe arranged between the hydraulic device (F) and the shaft ( 1 ) is connected to the housing of the casing comprising said discs ( 81 , 82 ) via a valve ( 86 , 87 ) adapted to produce discharge of the pressure in said housing via said pipe when the pressure in said housing is greater than or equal to a threshold value.