Hydraulic control arrangement for an automatic transmission

The invention claimed is: 1. A hydraulic control device for an automatic transmission, comprising: a housing: a valve device, the valve device further comprising: a switching valve ( 10 ) formed in the housing and hydraulically connected through the housing to a first pressure adjusting device (HCU) and a second pressure adjusting device (EDS), the switching valve also connected to a shift element (K) that transfers torque in the automatic transmission; a switching component ( 11 ); a check valve ( 20 ); wherein the pressure adjusting devices (HCU, EDS) are supplied with a pressure medium and, under effect of a switching pressure (p_S) at the switching component ( 11 ) generated by the second pressure adjusting device (EDS), the switching component ( 11 ) is moved into and held at a first switching position where the first pressure adjusting device (HCU) is hydraulically connected through the switching valve ( 10 ) to the shift element (K) such that a flow of pressure medium from the first pressure device (HCU) is supplied to the shift element (K); wherein below a certain value of the switching pressure (p_S), the switching component ( 11 ) is moved to a second switching position where inflow of the pressure medium from the first pressure adjusting device (HCU) at the shift element (K) is interrupted; the check valve ( 20 ) arranged such that, in the second switching position of the switching component ( 11 ), the pressure medium flows from the shift element (K) through the check valve ( 20 ) to a vented area of the hydraulic control device; and the switching valve ( 10 ) formed as a directional seat valve. 2. The hydraulic control device according to claim 1 , wherein the check valve ( 20 ) is arranged in the switching component ( 11 ) of the switching valve ( 10 ). 3. The hydraulic control device according to claim 1 , wherein the check valve ( 320 ) and the switching valve ( 310 ) are arranged separately in the housing ( 330 ) of the hydraulic control device. 4. The hydraulic control device according to claim 1 , wherein the switching component comprises a seat piston ( 11 ) having a first and a second cylindrical piston section ( 41 , 42 ), the first piston section ( 41 ) having a diameter that is smaller than a diameter of the second piston section ( 42 ), the seat piston further comprising a radially extending annular surface between the first and second piston sections ( 41 , 42 ) resulting from a difference between the two diameters, the annular surface defining a switching pressure surface ( 18 ). 5. The hydraulic control device according to claim 4 , wherein: the seat piston ( 11 ) is guided in an axially displaceable manner into a stepped bore ( 38 ) formed in the housing ( 30 ); in the first switching position, a first end ( 45 ) of the seat piston ( 11 ) abuts on a stop ( 13 ); in the second switching position, a second end ( 46 ) of the seat piston abuts on a valve seat ( 39 ) formed in the housing ( 30 ); the stepped bore ( 38 ) is radially penetrated by a coupling channel ( 35 ) to the shift element 9 K), a supply channel ( 36 ) from the first pressure adjusting device (HCU), and a switching pressure channel ( 37 ) from the second pressure adjusting device (EDS); and the switching pressure channel ( 37 ) arranged such that the switching pressure surface ( 18 ) of the seat piston ( 11 ) is subjected to the switching pressure (p_S) acting in the switching pressure channel ( 37 ) in each of the first and second switching positions of the seat piston ( 11 ). 6. The hydraulic control device according to claim 5 , wherein the switching valve ( 10 ) further comprises: a pressure spring ( 12 ) arranged between the seat piston ( 11 ) and the stop ( 13 ) fixed within the housing; wherein upon pressurization of the switching pressure surface ( 18 ) by the switching pressure (p_S), the switching component ( 11 ) is displaceable in an axial direction of a central axis (M) of the switching valve ( 10 ) against a force of the pressure spring ( 12 ) in the first switching position; and wherein with an unpressurized switching pressure channel ( 37 ) or a vented second pressure adjusting device (EDS), the seat piston ( 11 ) occupies the second switching position due to the force of the switching valve spring ( 12 ). 7. The hydraulic control device according to claim 1 , wherein the check valve ( 20 ) is formed as a seat valve having a seat piston ( 21 , 321 ) and a check valve spring ( 23 ) arranged between a check valve stop ( 15 , 315 ) and the seat piston ( 21 , 321 ), wherein a closing force of the check valve spring biases the seat piston ( 21 , 321 ) in the direction of a check valve seat ( 17 , 317 ). 8. The hydraulic control device according to claim 7 , wherein the switching component comprises a seat piston ( 11 ), wherein the check valve stop ( 15 ) and the check valve seat ( 17 ) are formed in the seat piston ( 11 ) of the switching component. 9. The hydraulic control device according to claim 7 , wherein the check valve stop ( 315 ) and the check valve seat ( 317 ) are formed in the housing ( 330 ) of the hydraulic control device. 10. The hydraulic control device according to claim 1 , wherein in the second switching position of the switching component ( 11 ) and above a shift element pressure value (p_K*): the check valve ( 20 ) permits pressure medium flow from the shift element (K) to the first or the second pressure adjusting device (EDS, HCU) if the pressure (p_S, p_HCU) of the respective pressure adjusting device is lower than the shift element pressure (p_K) or corresponds to ambient pressure (p_ 0 ); and the check valve ( 20 ) blocks flow of the pressure medium from the respective pressure adjusting devices (EDS, HCU) to the shift element (K). 11. The hydraulic control device according to claim 10 , wherein in the second switching position of the switching component ( 11 ), the shift element (K) is hydraulically connected through the check valve ( 20 ) and a connection channel ( 214 ) formed in the switching component ( 11 ) to the second pressure adjusting device (EDS). 12. The hydraulic control device according to claim 10 , wherein in the second switching position of the switching component ( 11 ), the shift element (K) is hydraulically connected through the check valve ( 20 ) and a connection channel ( 14 ) formed in the switching component ( 11 ) to the first pressure adjusting device (HCU). 13. The hydraulic control device according to claim 10 , wherein in the second switching position of the switching component ( 11 ), the shift element (K) is hydraulically connected through the check valve and a connection channel ( 314 ) formed in the housing ( 330 ) to the first pressure adjusting device (HCU). 14. The hydraulic control device according to claim 10 , wherein in the second switching position of the switching component ( 11 ), the shift element is hydraulically connected through the check valve and a connection channel formed in the housing to the second pressure adjusting device. 15. An automatic transmission, comprising a hydraulic control device in accordance with claim 1 .