Rudder control assembly for a missile

The invention claimed is: 1. A rudder control assembly ( 2 ) for a missile ( 1 ), the rudder control assembly ( 2 ) comprising: a first actuator ( 20 ) connectable to a rudder ( 16 ), which first actuator ( 20 ) is configured to steer the rudder ( 16 ) when connected to the rudder ( 16 ); a coupling element ( 22 ) for connecting the first actuator ( 20 ) to the rudder ( 16 ); and a second actuator ( 24 ) for locking the rudder ( 16 ) in a fixed position, wherein the second actuator ( 24 ) comprises a locking element ( 26 ), which is configured to lock and unlock the rudder ( 16 ) and which locking element ( 26 ) also is configured to connect the first actuator ( 20 ) with the rudder ( 16 ) by means of the coupling element ( 22 ) when unlocking the rudder ( 16 ). 2. The rudder control assembly ( 2 ) according to claim 1 , wherein the coupling element ( 22 ) comprises a first coupling piece ( 32 ) arranged on the first actuator ( 20 ) and second coupling piece ( 34 ) arranged on the rudder ( 16 ). 3. The rudder control assembly ( 2 ) according to claim 2 , wherein the first and second coupling pieces ( 32 , 34 ) have complementary shapes. 4. The rudder control assembly ( 2 ) according to claim 3 , wherein the complementary shapes of the first and second coupling pieces ( 32 , 34 ) are conically shapes. 5. The rudder control assembly ( 2 ) according to claim 2 , wherein the second coupling piece ( 34 ) arranged on the rudder ( 16 ) comprises an axially movable shaft ( 36 ). 6. The rudder control assembly ( 2 ) according to claim 5 , wherein the first coupling piece ( 32 ) comprises a bore ( 38 ), which is configured to receive the axially movable shaft ( 36 ). 7. The rudder control assembly ( 2 ) according to claim 5 , wherein a spring element ( 40 ) is arranged to axially move the axially movable shaft ( 36 ) towards the first coupling piece ( 32 ). 8. The rudder control assembly ( 2 ) according to claim 5 , wherein: the axially movable shaft ( 36 ) in a first axial position is configured to be locked by the locking element ( 26 ) and disconnected from first coupling piece ( 32 ), and the axially movable shaft ( 36 ) in a second axial position is configured to be released by the locking element ( 26 ) and connected to the first coupling piece ( 32 ). 9. The rudder control assembly ( 2 ) according to claim 8 , wherein the locking element ( 26 ) comprises a movable pin ( 42 ) connected to the second actuator ( 24 ), which movable pin ( 42 ) is configured to be received in a recess ( 44 ) in the axially movable shaft ( 36 ). 10. The rudder control assembly ( 2 ) according to claim 9 , wherein the locking element ( 26 ) comprises a groove ( 46 ), which is configured to receive a protrusion ( 48 ) of the axially movable shaft ( 36 ) when the axially movable shaft ( 36 ) is locked in the first axial position, and which protrusion ( 48 ) is configured to leave the groove ( 46 ) when the axially movable shaft ( 36 ) is situated in the second axial position and connected to the first coupling piece ( 32 ). 11. A missile ( 1 ), comprising a rudder control assembly ( 2 ) according to claim 1 . 12. A method, performed by a control device ( 100 ), for testing a first actuator ( 20 ) of a rudder control assembly ( 2 ) for a missile ( 1 ), which first actuator ( 20 ) is connectable to a rudder ( 16 ), and which first actuator ( 20 ) is configured to steer the rudder ( 16 ) when connected to the rudder ( 16 ); the rudder control assembly ( 2 ) comprising: a coupling element ( 22 ) for connecting the first actuator ( 20 ) to the rudder ( 16 ); and a second actuator ( 24 ) for locking the rudder ( 16 ) in a fixed position, wherein the second actuator ( 24 ) comprises a locking element ( 26 ), which is configured to lock and unlock the rudder ( 16 ) and which locking element ( 26 ) also is configured to connect the first actuator ( 20 ) with the rudder by means of the coupling element ( 22 ) when unlocking the rudder ( 16 ), the method comprising: activating (s 101 ) the first actuator ( 20 ) to move when the rudder ( 16 ) is locked in the fixed position, and determining (s 102 ) if the first actuator ( 20 ) moves when activated. 13. The method according to claim 12 , wherein the method further comprises activating (s 103 ) the second actuator ( 24 ) for unlocking the rudder ( 16 ), if it is determined that first actuator ( 20 ) moves when activated. 14. A computer program (P) comprising instructions which, when the program (P) is executed by a computer ( 100 ; 500 ), cause the computer ( 100 ; 500 ) to carry out the method according to claim 12 . 15. A non-transitory computer-readable medium comprising instructions, which when executed by a computer ( 100 ; 500 ), cause the computer ( 100 ; 500 ) to carry out the method according to claim 12 .