Round baler with position controlled take-up roller, and method of operating a round baler

1 . A round baler comprising: a housing; a gate rotatably attached to the housing for rotation about a gate rotation axis between a closed position and an open position; a forming belt defining a baling chamber and operable to form crop material into a bale having a cylindrical shape; a take-up roller moveably coupled to one of the gate or the housing and supporting the forming belt; a first actuator coupled to the take-up roller and operable to automatically apply a first bias force to the take-up roller to urge the take-up roller into a slack take-up position to reduce slack in the forming belt as the gate moves relative to the housing; and a second actuator coupled to the take-up roller and operable to apply a second bias force to the take-up roller, wherein the second bias force is applied in opposition to the first bias force to control movement of the take-up roller as the gate moves relative to the housing. 2 . The round baler set forth in claim 1 , further comprising a take-up shaft defining a shaft axis and attached to the take-up roller, with the take-up roller rotatable with the take-up shaft about the shaft axis. 3 . The round baler set forth in claim 2 , wherein the take-up shaft is rotatably attached to the gate. 4 . The round baler set forth in claim 2 , further comprising a roller lever attached to and rotatable with the take-up shaft about the shaft axis and interconnecting the take-up shaft and the take-up roller. 5 . The round baler set forth in claim 2 , wherein the first actuator and the second actuator are coupled to the take-up shaft. 6 . The round baler set forth in claim 5 , further comprising an actuator lever interconnecting the take-up shaft and the first actuator. 7 . The round baler set forth in claim 5 , further comprising an actuator lever interconnecting the take-up shaft and the second actuator. 8 . The round baler set forth in claim 1 , wherein the first actuator includes a spring. 9 . The round baler set forth in claim 8 , wherein the first spring of the first actuator includes a coil spring. 10 . The round baler set forth in claim 1 , wherein the second actuator includes a linear actuator selectively controllable to extend and retract along a linear path. 11 . The round baler set forth in claim 10 , wherein the linear actuator of the second actuator is a hydraulic cylinder having a first end coupled to the take-up roller and a second end coupled to one of the housing or the gate. 12 . The round baler set forth in claim 1 , further comprising a baler controller having a processor and a memory having a gate control algorithm saved thereon, wherein the processor is operable to execute the gate control algorithm to: control the second actuator to act in opposition to the first actuator, when the gate moves from the closed position to an intermediate position disposed between the closed position and the open position, such that the forming belt exhibits a first amount of tension for a period of time while the gate is disposed in the intermediate position, whereby the forming belt does not rotate through an endless loop when the forming belt exhibits the first amount of tension. 13 . The round baler set forth in claim 12 , wherein the processor is operable to execute the gate control algorithm to control the second actuator to generate the second bias force to include a magnitude sufficient to overcome the first bias force from the first actuator when the gate moves between the closed position and the intermediate position. 14 . The round baler set forth in claim 13 , wherein the processor is operable to execute the gate control algorithm to control the second actuator to maintain the second bias force at the magnitude sufficient to overcome the first bias force from the first actuator for the period of time the gate is disposed in the intermediate position. 15 . The round baler set forth in claim 12 , wherein the processor is operable to execute the gate control algorithm to control the second actuator to allow the first bias force from the first actuator to move the take-up roller into the slack take-up position after the period to time, such that the forming belt exhibits a second amount of tension that is less than the first amount of tension. 16 . The round baler set forth in claim 15 , wherein the processor is operable to execute the gate control algorithm to control the second actuator to generate the second bias force to include a magnitude less than the first bias force from the first actuator when the gate moves between the intermediate position and the open position. 17 . A method of controlling a round baler having a variable size baling chamber for forming a bale having a cylindrical shape, the method comprising: forming crop material into a bale having a cylindrical shape with a forming belt circulating in an endless loop about a plurality of rollers, wherein at least one of the plurality of rollers is a take-up roller operable to decrease slack in the forming belt when a gate of the round baler is opened, and at least one of the plurality of rollers is a drive roller operable to drive the forming belt in the endless loop through frictional engagement between the forming belt and the drive roller; moving the gate of the round baler relative to a housing of the round baler from a closed position into an intermediate position when formation of the bale is complete within the baling chamber; and counteracting a first bias force from a first actuator urging the take-up roller into a slack take-up position, with a second bias force from a second actuator, to introduce a first amount of tension in the forming belt as the gate moves from the closed position into the intermediate position, such that the first amount of tension in the forming belt generates a friction force between the drive roller and the forming belt insufficient to maintain movement of the forming belt in the endless loop around the plurality of rollers. 18 . The method set forth in claim 17 , further comprising maintaining the gate in the intermediate position with the first amount of tension in the forming belt for a period of time. 19 . The method set forth in claim 18 , further comprising moving the gate relative to the housing from the intermediate position into an open position after the period of time. 20 . The method set forth in claim 18 , further comprising reducing the second bias force from the second actuator to allow the first bias force from the first actuator to move the take-up roller into the slack take-up position after the period of time such that the forming belt exhibits a second amount of tension, wherein the second amount of tension in the forming belt generates a friction force between the drive roller and the forming belt sufficient to maintain movement of the forming belt in the endless loop around the plurality of rollers.