Valve arrangement for multi-flow turbine

What is claimed is: 1. A valve arrangement ( 100 ) for a multi-channel turbine ( 10 ), comprising: a housing section ( 300 ) with a first volute ( 320 ), with a second volute ( 340 ) and with a connecting region ( 360 ) between the first volute ( 320 ) and the second volute ( 340 ); a valve body ( 110 ) for closing off the connecting region ( 360 ) in a closed position of the valve body ( 110 ); wherein a wall region ( 370 ) of the housing section ( 300 ) is arranged in the connecting region ( 360 ) and is situated opposite the valve body ( 110 ) in the closed position, wherein a shape of the wall region ( 370 ) is configured to be optimized in terms of flow to increase, during operation of the valve arrangement ( 100 ), a rate of flow transfer of exhaust gas between the first volute ( 320 ) and the second volute ( 340 ) in an open position of the valve body ( 110 ), wherein the housing section ( 300 ) has a bypass opening ( 350 ), and the valve arrangement ( 100 ) is designed for regulation of the bypass opening ( 350 ), and wherein the valve body ( 110 ) is configured in such a way that, with an adjustment of the valve body ( 110 ) from the closed position into the open position, firstly only the connecting region ( 360 ), for flow transfer of exhaust gases between the first volute ( 320 ) and the second volute ( 340 ), is opened up continuously, and from a particular degree of opening of the valve body ( 110 ), additionally the bypass opening ( 350 ) is opened continuously. 2. The valve arrangement as claimed in claim 1 , wherein the wall region ( 370 ) is formed to be at least partially rounded in order to increase the rate of flow transfer. 3. The valve arrangement as claimed in claim 1 , wherein the housing section ( 300 ) has a separating wall ( 310 ) between the first volute ( 320 ) and the second volute ( 340 ), and the connecting region ( 360 ) is in the form of a cutout in the separating wall ( 310 ), and wherein the wall region ( 370 ) is a section of the separating wall ( 310 ) and has an outer contour ( 371 ). 4. The valve arrangement as claimed in claim 3 , wherein a first cross-sectional plane (E 1 ) is spanned by a length direction ( 312 ) of the separating wall ( 310 ) and a height direction ( 314 ) of the separating wall ( 310 ), a second cross-sectional plane (E 2 ) is spanned by a thickness direction ( 316 ) of the separating wall ( 310 ) and the height direction ( 314 ), and a third cross-sectional plane (E 3 ) is spanned by the thickness direction ( 316 ) and the length direction ( 312 ). 5. The valve arrangement as claimed in claim 4 , wherein, in the second cross-sectional plane (E 2 ) and/or the third cross-sectional plane (E 3 ), the outer contour ( 371 ) is formed to be at least partially circular with a constant radius (R 1 ). 6. The valve arrangement as claimed in claim 5 , wherein the radius (R 1 ) lies in the range from 2 mm to 100 mm. 7. The valve arrangement as claimed in claim 4 , wherein, in the second cross-sectional plane (E 2 ) and/or the third cross-sectional plane (E 3 ), the outer contour ( 371 ) is formed to be at least partially rounded with a variable radius (R 1 ), in particular wherein the radius (R 1 ) varies in the range from 2 mm to 100 mm, in particular varies in the range from 5 mm to 80 mm. 8. The valve arrangement as claimed in claim 7 , wherein the radius (R 1 ) varies in the range from 2 mm to 100 mm. 9. The valve arrangement as claimed in claim 4 , wherein, in the second cross-sectional plane (E 2 ) and/or the third cross-sectional plane (E 3 ), the outer contour ( 371 ) has two straight sections ( 372 , 373 ; 374 , 375 ) in the height direction ( 314 ) and a transition section ( 376 ) situated therebetween, wherein the transition section ( 376 ) is situated opposite the valve body ( 110 ) in the closed position. 10. The valve arrangement as claimed in claim 9 , wherein the straight sections ( 372 , 373 ) are formed to be substantially parallel to one another; or wherein the straight sections ( 374 , 375 ) run obliquely toward one another in the direction of the transition section ( 376 ). 11. The valve arrangement as claimed in claim 10 , wherein when the straight sections ( 372 , 373 ) are formed to be substantially parallel to one another, the straight sections ( 372 , 373 ) run in the height direction ( 314 ). 12. The valve arrangement as claimed in claim 9 , wherein the transition section ( 376 ) has first and second rounded transition regions ( 376 a , 376 b ) and a straight bridge section ( 376 c ) situated therebetween. 13. The valve arrangement as claimed in claim 4 , wherein, in the second cross-sectional plane (E 2 ) and/or the third cross-sectional plane (E 3 ), the outer contour has at least one undercut ( 378 ). 14. The valve arrangement as claimed in claim 4 , wherein an extent of the wall region ( 370 ) in the height direction ( 314 ) directly below the base section ( 116 ) of the valve body ( 110 ), viewed in the closed position, lies in the range from 1 mm to 30 mm; or wherein an extent of the wall region ( 370 ) in the height direction ( 314 ) directly below the base section ( 116 ) of the valve body ( 110 ), viewed in the closed position, approaches zero. 15. The valve arrangement as claimed in claim 14 , wherein an extent of the wall region ( 370 ) in the height direction ( 314 ) directly below the base section ( 116 ) of the valve body ( 110 ), viewed in the closed position, lies in the range from 5 mm to 25 mm. 16. The valve arrangement as claimed in claim 1 , wherein the valve body ( 110 ) is designed to close off, in the closed position, both the bypass opening ( 350 ) and the connecting region ( 360 ). 17. A multi-channel turbine ( 10 ) for a supercharging device, comprising: a turbine wheel ( 20 ); and a turbine housing ( 30 ); characterized by a valve arrangement ( 100 ) as claimed in claim 1 , wherein the housing section ( 300 ) is formed as part of the turbine housing ( 30 ). 18. A supercharging device for an internal combustion engine, comprising: a compressor ( 40 ) and a multi-channel turbine ( 10 ) as claimed in claim 17 , wherein the multi-channel turbine ( 10 ) is coupled rotatably to the compressor ( 40 ).