A wrapping assembly includes: a material roll that holds a roll of wrapping material; a duckbill assembly including a duckbill carrying a duckbill roll that draws material from a roll of wrapping material held by the material roll, the duckbill being movable between a first position and a second position; a duckbill actuator coupled to the duckbill that moves the duckbill between the first position and the second position; a variable brake associated with the material roll that applies a variable braking force to the material roll; and a controller operatively coupled to the duckbill actuator and the brake. The controller determines that a load on the duckbill actuator exceeds a threshold value and outputs a brake reduction signal to the brake so the brake reduces applied braking force to the material roll when the load on the duckbill actuator exceeds the threshold value.

An intermittent drive system includes a rotatable output component, a rotating input component with a driving engagement element, a synchronizing ring and a decoupling ring. The synchronizing ring is coupled to the output element to rotate therewith. The synchronizing ring has a driven engagement element configured to selectively engage with the driving engagement element. The synchronizing ring has an alignment feature configured to rotationally align the driving engagement element with the driven engagement element and has a decoupling feature configured to selectively disengage the driving engagement element from the driven engagement element. The decoupling ring is selectively coupled to the input component and has a decoupling feature configured to selectively engage the decoupling feature of the synchronizing ring. The driving engagement element engages the driven engagement element only when both the alignment feature is rotationally oriented to align the driving engagement element with the driven engagement element and the decoupling features are rotationally oriented to allow the driving engagement element to engage the driven engagement element.

The invention discloses a knotter driven by double fluted disc. The knotter driven by double fluted disc comprises a small fluted disc, a knotter rack, a large fluted disc, a cutter arm assembled on the knotter rack, a knotter jaw and bill hook combined mechanism (R), a rope gripper driving mechanism (Q) and a rope gripper (J), wherein a composite fluted disc of traditional D-knotter is divided into the small fluted disc and the large fluted disc in the knotter driven by double fluted disc.

A baler including a needle yoke driven via a needle coupling device including a connection member pivotally mounted around a fixed pivot axis for swinging around the fixed pivot axis. The swinging corresponds to movement of the needle yoke. The connection member is cooperative with the needle yoke by (i) a shearbolt adapted to transfer a force from the connection member to the needle yoke during a forward movement and (ii) by a protrusion, formed at one of the connection member and the needle yoke, to abut against the other one of the connection member and the needle yoke during a backward movement of the needle yoke.

A baler including a bale chamber; a plunger to compress crop material in the bale chamber to form a bale; a plurality of knotters; a needle yoke with a plurality of needles to deliver a plurality of lower strands through the bale chamber to the plurality of knotters; a tucker arm shaft carrying a plurality of tucker arms to deliver a plurality of upper strands to the plurality of knotters; a driving shaft located above the bale chamber and extending in a traverse direction of the baler; wherein the tucker arm shaft extends parallel to the driving shaft; a tucker arm coupling device to covert the rotation of the driving shaft into a rotation of the tucker arm shaft; a needle coupling device to convert a rotation of the driving shaft into a movement of the needle yoke from a rest position to a twine delivery position and back.

A baler including a bale chamber; a plunger configured to compress crop material in the bale chamber in order to form a bale; a needle yoke with a plurality of needles configured to deliver twine through the bale chamber; a plurality of knotters configured to receive the twine from the plurality of needles; a bale length measurement and trigger device configured to measure the length of the bale in the bale chamber and to generate a trigger when a predetermined length is reached; a driving shaft located above the bale chamber and extending in a traverse direction of the baler; a needle coupling device between the driving shaft and the needle yoke, the needle coupling device being configured for moving the needle yoke from a rest position to a twine delivery position and back, when the bale length measurement and trigger device generates a trigger.

A knotter for a baler, the knotter including a knotting system with at least one movable part, and a driver, operatively connected to the at least one movable part. The knotter is further provided with a first cover, associated with at least one movable part, having a first covering position wherein the first cover at least partly covers the at least one movable part, and a second uncovering position, wherein the first cover no longer covers the at least one movable part. The knotter further includes a safety mechanism, operatively connected to the driver and the first cover, such that positioning or enabling the positioning of the first cover in the second uncovering position stops the moving of the at least one movable part.

Bale measuring method for a rectangular baler includes the steps of: measuring a movement of a binding material that is being tied around a bale; using the measured movement of the binding material to calibrate a measurement and calculation tool for measuring a movement of the bale in the baler and for calculating a length of the bale based on said measurement; determining the length of the bale using the calibrated measurement and calculation tool as the bale moves backward in the baler.

An intermittent drive system includes a rotatable output component, a rotating input component with a driving engagement element, a synchronizing ring and a decoupling ring. The synchronizing ring is coupled to the output element to rotate therewith. The synchronizing ring has a driven engagement element configured to selectively engage with the driving engagement element. The synchronizing ring has an alignment feature configured to rotationally align the driving engagement element with the driven engagement element and has a decoupling feature configured to selectively disengage the driving engagement element from the driven engagement element. The decoupling ring is selectively coupled to the input component and has a decoupling feature configured to selectively engage the decoupling feature of the synchronizing ring. The driving engagement element engages the driven engagement element only when both the alignment feature is rotationally oriented to align the driving engagement element with the driven engagement element and the decoupling features are rotationally oriented to allow the driving engagement element to engage the driven engagement element.

An agricultural baler includes a needle disposed within a baling chamber. The needle transfers a strap to a gripping device. A needle gripper is disposed on a distal end of the needle and configured to selectively secure the strap to the needle. The needle gripper includes a thumb gripper rotatably mounted to a wall of the needle gripper. The thumb gripper rotates between a first position configured to secure the strap against a surface of the needle and a second position configured to release the strap from the needle. The needle gripper includes a release arm coupled to the thumb gripper and configured to rotate the thumb gripper from the first position to the second position in response to rotation of the release arm about a release arm axis from a neutral position to a first release position.