Device for producing a gear green compact

What is claimed is: 1. A device ( 21 ) for producing a gear green compact ( 43 ) from a metallic powder, comprising a die ( 31 ) for receiving the metallic powder, an upper stamp ( 25 ) and a lower stamp ( 32 ), which are designed to be immersible into the die ( 31 ), wherein the die ( 31 ) has at least one helical toothing on an inner lateral surface ( 44 ), which helical toothing extends only over a partial area of the circumference of the inner lateral surface ( 44 ), and which has a first helix angle, wherein, adjoining the first helical toothing in a circumferential direction ( 9 ), one toothed edge surface ( 45 , 46 ) is formed on each side, both of which have a second helix angle ( 47 ); wherein the lower stamp ( 32 ) has a lower stamp helical toothing on an outer lower stamp lateral surface ( 48 ), which helical toothing extends only over a partial area of the circumference of the lower stamp lateral surface ( 48 ), and which has the first helix angle of the die ( 31 ), wherein, adjoining the helical toothing in a circumferential direction ( 9 ), one toothed edge surface ( 49 , 50 ) is formed on each side, both of which have a third helix angle ( 51 ); wherein upper stamp ( 25 ) has an upper stamp helical toothing on an outer upper stamp lateral surface ( 52 ), which helical toothing extends only over a partial area of the circumference of the upper stamp lateral surface ( 52 ), and which has the first helix angle of the helical toothing of the die ( 31 ), wherein, adjoining the helical toothing in a circumferential direction ( 9 ), one toothed edge surface ( 53 , 54 ) is formed on each side, both of which have a fourth helix angle ( 55 ); and wherein at least one of the second helix angles ( 47 ) of the die ( 31 ) is unequal to the first helix angle of the helical toothing of the die ( 31 ). 2. The device ( 21 ) according to claim 1 , wherein the second helix angle ( 47 ) of the die ( 31 ) is unequal to the first helix angle of the die ( 31 ) by a value amounting to between 0.005° and 0.05°. 3. The device ( 21 ) according to claim 1 , wherein the difference between the second helix angle ( 47 ) and the first helix angle of the die ( 31 ) has a value which is calculated according to the formula INV SIN (RA/H), wherein RA refers to the maximum radial distance ( 57 ) between the die ( 31 ) and the lower stamp ( 32 ) or upper stamp ( 25 ) and H is a height ( 58 ) of the die, in each case given in mm. 4. The device ( 21 ) according to claim 1 , wherein at least one of the third helix angles ( 51 ) of the lower stamp ( 32 ) and/or at least one of the fourth helix angles ( 55 ) of the upper stamp ( 25 ) is unequal to the first helix angle of the helical toothing of the die ( 31 ). 5. The device ( 21 ) according to claim 4 , wherein the third helix angle ( 51 ) of the lower stamp ( 32 ) and/or the fourth helix angle ( 55 ) of the upper stamp ( 25 ) is unequal to the first helix angle by a value amounting to between 0.005° and 0.05°. 6. The device ( 21 ) according to claim 4 , wherein the difference between the third helix angle ( 51 ) of the lower stamp ( 32 ) and the first helix angle and/or the fourth helix angle ( 55 ) of the upper stamp ( 25 ) and the first helix angle has a value which is calculated according to the formula INV SIN (RA/H), wherein RA refers to the maximum radial distance ( 57 ) between the die ( 31 ) and the lower stamp ( 32 ) or the upper stamp ( 25 ) and H is a height ( 58 ) of the die ( 31 ), in each case given in mm. 7. The device ( 21 ) according to claim 1 , wherein the second helix angle ( 47 ) of the die ( 31 ) is smaller than the first helix angle of the helical toothing of the die ( 31 ). 8. The device ( 21 ) according to claim 4 , wherein the third helix angle ( 51 ) of the lower stamp ( 32 ) and/or the fourth helix angle ( 55 ) of the upper stamp ( 25 ) is or are smaller than the first helix angle of the helical toothing of the die ( 31 ). 9. The device ( 21 ) according to claim 4 , wherein the third helix angle ( 51 ) of the lower stamp ( 32 ) and/or the fourth helix angle ( 55 ) of the upper stamp ( 25 ) is or are greater than the second helix angle of the die ( 31 ). 10. The device ( 21 ) according to claim 4 , wherein the third helix angle ( 51 ) of the lower stamp ( 32 ) and/or the fourth helix angle ( 55 ) of the upper stamp ( 25 ) is formed only across a partial area of the height of the toothed edge surface ( 48 , 49 or 53 , 54 ), and wherein the remaining partial area of the height is formed having at least a helix angle different from the third helix angle ( 47 ) of the lower stamp ( 32 ) and/or from the fourth helix angle ( 55 ) of the upper stamp ( 25 ). 11. A method for producing a sintered gear ( 1 ) comprising the steps: providing a metallic powder; pressing the powder to form a gear green compact ( 43 ); possibly green machining the gear green compact ( 43 ); and sintering the gear green compact ( 43 ); wherein the pressing of the powder to form a gear green compact ( 43 ) is carried out in a device ( 21 ) for producing the gear green compact ( 43 ) from the metallic powder, comprising a die ( 31 ) for receiving the metallic powder, an upper stamp ( 25 ) and a lower stamp ( 32 ), which are designed to be immersible into the die ( 31 ), wherein the die ( 31 ) has at least one helical toothing on an inner lateral surface ( 44 ), which helical toothing extends only over a partial area of the circumference of the inner lateral surface ( 44 ), and which has a first helix angle, wherein, adjoining the first helical toothing in a circumferential direction ( 9 ), one toothed edge surface ( 45 , 46 ) is formed on each side, both of which have a second helix angle ( 47 ); wherein the lower stamp ( 32 ) has a lower stamp helical toothing on an outer lower stamp lateral surface ( 48 ), which helical toothing extends only over a partial area of the circumference of the lower stamp lateral surface ( 48 ), and which has the first helix angle of the die ( 31 ), wherein, adjoining the helical toothing in a circumferential direction ( 9 ), one toothed edge surface ( 49 , 50 ) is formed on each side, both of which have a third helix angle ( 51 ); wherein upper stamp ( 25 ) has an upper stamp helical toothing on an outer upper stamp lateral surface ( 52 ), which helical toothing extends only over a partial area of the circumference of the upper stamp lateral surface ( 52 ), and which has the first helix angle of the helical toothing of the die ( 31 ), wherein, adjoining the helical toothing in a circumferential direction ( 9 ), one toothed edge surface ( 53 , 54 ) is formed on each side, both of which have a fourth helix angle ( 55 ); and wherein at least one of the second helix angles ( 47 ) of the die ( 31 ) is unequal to the first helix angle of the helical toothing of the die ( 31 ). 12. The method according to claim 11 , wherein the extent of the absolute value of the deviation of the second helix angle ( 47 ) of at least one of the toothed edge surfaces ( 45 , 46 ) from the first helix angle of the helical toothing of the die ( 31 ) is selected dependent on a pressure force at which the metallic powder is compacted to form the gear green compact ( 43 ), wherein (p*S)/100,000=ΔS applies, wherein p is the pressure force given in [MPa], S is the first helix angle given in [° ] and ΔS is the deviation from the first helix angle given in [° ]. 13. A sintered gear ( 1 ) comprising a gear body ( 2 ), which has a lateral surface ( 3 ) and two end faces ( 4 , 5 ), wherein at least one helical toothing ( 6 ) is arranged on the lateral surface ( 3 ), which helical toothing ( 6 ) extends only over a partial area of the circum