Adjustable baler feeder duct

The invention claimed is: 1. Agricultural baler comprising: a wheeled frame; a baling chamber mounted to said frame and extending generally fore-and-aft with respect to an intended direction of movement of the baler and having an inlet opening in a lower wall thereof; a compression surface mounted for reciprocation within the baling chamber for compressing crop material fed through said inlet opening into said baling chamber to form a bale thereof; a feeder comprising tines to stuff crop material from a feeder duct into the baling chamber, the feeder duct communicating at one end with the inlet opening in the baling chamber and curving downwardly and forwardly there from and terminating in a lower, forwardly facing open crop receiving mouth; the feeder duct comprising upper and lower curved walls of which the upper wall comprises slots, extending generally from said crop receiving mouth to said inlet opening in the baling chamber for cooperation with said tines; an adjusting mechanism for setting an upper end of the upper wall in a predetermined position, and a lower end of the upper wall is designed to pivot around an axis near an entry point of the feeder into the lower end of the upper wall. 2. Baler according to claim 1 , wherein the lower wall is fixedly mounted. 3. Baler according to claim 1 , wherein the adjusting mechanism comprises at least one of an hydraulic actuator, an electrical actuator and a threaded rod. 4. Baler according to claim 1 , wherein the upper wall is formed by transversely spaced apart elongated wall members defining slots there between, extending generally from said crop receiving mouth to said inlet opening in the baling chamber. 5. Baler according to claim 4 , wherein an upper end of each of said elongated wall members is connected to an elongated connector member, positioned outside and transversal to the width of the feeder duct, comprising at least one shaft extending from said elongated connector member at at least one end of the connector member, the elongated connector member fixing said elongated wall members and defining the slots there between. 6. Baler according to claim 5 , wherein the elongated connector member comprises a number of recesses, each recess of the number of recesses corresponding to one of said slots and communicating therewith, the recesses having dimensions selected to accommodate the movement of said feeder. 7. Baler according to claim 5 , wherein the at least one shaft communicates with an elongated guide slot adapted to receive said shaft, in a guide plate substantially perpendicular to said elongated connector member. 8. Baler according to claim 7 , wherein an orientation of the elongated guide slot is such that the elongated guide slot is longitudinally parallel aligned with the average force on an upper member. 9. Baler according to claim 4 , wherein one shaft is connected to a piston of an actuator which is able to move and set the upper wall relative to the lower wall. 10. Baler according to claim 4 , wherein the actuator is pivotally positioned next to and between the lower wall and the upper wall. 11. Baler according to claim 3 , wherein the lower end of said elongated wall members defining slots there between is pivotable connected to a hinge arrangement, such that each elongated wall member may pivot on an axis perpendicular to the displacement of the elongated wall member. 12. Baler according to claim 3 , wherein the upper end of the elongated wall members may perform a circular trajectory from 0 up to and including 10 degrees. 13. Baler according to claim 1 , further comprising at least one of a charge sensor, controller and cycle sensor. 14. Baler according to claim 3 , wherein displacement of the inner wall of the feeder duct by the actuator is controlled by the charge sensor. 15. Baler according to claim 14 , wherein the charge sensor comprises at least one of a trip sensor, positioned in the feeder duct, and an infrared sensor positioned in the feeder duct. 16. Method of operation of an agricultural baler, comprising: a wheeled frame; a baling chamber mounted to said frame and extending generally fore-and-aft with respect to an intended direction of movement of the baler and having an inlet opening in a lower wall thereof; a plunger mounted for reciprocation within the baling chamber for compressing crop material fed through said inlet opening into said baling chamber to form a bale thereof; a feeder comprising tines to stuff crop material from a feeder duct into the baling chamber, the feeder duct communicating at one end with the inlet opening in the baling chamber and curving downwardly and forwardly there from and terminating in a lower, forwardly facing open crop receiving mouth; the feeder duct comprising upper and lower curved walls of which the upper wall comprises slots, extending generally from said crop receiving mouth to said inlet opening in the baling chamber for cooperation with said feeder; an adjusting mechanism for setting an upper end of the upper wall in a predetermined position, and the lower end of the upper wall is designed to pivot around an axis near the entry point of the feeder into a lower end of the upper wall; and a control system comprising a controller configured for informing an operator on baler operation, Wherein the method comprises the steps of calculating with the controller a value related to a ratio of an actual intake rate of crop material by said feeder compared to an optimum intake ratio and setting the upper end of the upper wall in a predetermined position based on said value related to the ratio of the actual intake rate of crop material by said feeder compared to an optimum intake ratio. 17. Method according to claim 16 , further comprising-the steps of: monitoring through the controller a degree of compression of the crop material fed into the feeder duct; providing an output to said control system when said crop material reaches a pre-determined degree of compression; and using the output for calculating a value related to said actual intake rate. 18. Method according to claim 16 , wherein said optimum intake rate is equal to a crop intake rate at which said predetermined degree of compression is reached in one cycle of said plunger. 19. A method according to claim 16 , further comprising providing a representation of said value on a display of the control system.