A square baler has a press channel, a knotter arranged on the press channel, a blower and flow guide element, which is moveable between a first position, in which the flow guide element directs a blowing air stream of the blower onto the knotter, and at least one second position, in which the flow guide element directs the blowing air stream past the knotter.

A knotter table of a baler includes a plurality of tucker finger assemblies which each aid in tying together ends of a set of twine strands so as to tie a loop of twine about a bale formed in a baling chamber. Each tucker finger assembly includes a tucker finger defined by a plate pivotally mounted alongside a baling chamber needle slot for being pivoted horizontally between a standby position, wherein the tucker finger is entirely to one side of the needle slot, and a working position, wherein the tucker finger is pivoted across the needle slot. A stop arrangement is provided for being engaged by the tucker finger or by an operating linkage coupled to the tucker finger in the event that the tucker finger pivots a preselected distance beyond a desired working range so as to prevent the operating linkage from going over-center and causing linkage damage.

A method for assigning information to an identification tag on a bale includes receiving, compressing and shaping crop material into a plurality of formed bales. At least one sensor parameter for the formed bales is detected with at least one sensor. Each bale is wrapped with a binding material and an identification tag is attached to each of the formed bales. A bale ID is created for each of the formed bales. The identification tag on the bale for each bale is assigned to the bale ID. The operator selects to have either the sensor parameter for the tagged bale associated with the bale ID or have a semi-randomized code not containing the sensor parameter associated with the bale ID.

A bale identification assembly for use with an agricultural baler (18) includes a first supply roll mounted on the baler providing a binding material (52) used by the knotter system to bind the formed bale, the binding material (52) on the first supply roll comprising identification tags (62) at spaced intervals along the binding material. The bale identification assembly includes a second supply roll mounted on the baler (18) providing a binding material without identification tags, wherein the knotter system combines the binding material with identification tags (62) from the first supply roll with the binding material without identification tags from the second supply roll to bind the formed bale. The bale identification assembly includes a read module with one or more antennas configured to transmit interrogator signals and also receive authentication replies from the identification tags (62).

A baler implement includes a housing defining a baling chamber for forming a bale having a parallelepiped shape, and a knotter system for wrapping and tying twine around the bale. A knotter controller is configured to determine a remaining length of a first twine in a first twine supply, and determine a remaining length of a second twine in a second twine supply. The knotter controller may then calculate an estimated remaining number of bales that may be secured based on the remaining length of the first twine and the second twine. The knotter controller may communicate an output signal to an output device indicating the estimated remaining number of bales that may be secured. The knotter controller may automatically communicate a resupply request when the first twine and/or the second twine are low.

A baling system comprising a first bale-forming area configured to form a first series of first individual bales, and a second bale forming-area configured to from a second series of second individual bales. The baling system additionally comprises a bale accumulator configured to receive the first and second individual bales from said first and second bale-forming areas and to manipulate the first and second individual bales into a group of four or more bales.

A baler implement a tag installer operable to attach an RFID identification tag to a bale. A reader is positioned to interrogate the identification tag for receiving data from the identification tag. The reader is operable to emit an interrogation signal for interrogating the identification tag in accordance with a pre-defined timing sequence. The reader emits the interrogation signal regardless of a position of the bale in the baling chamber or on the baler implement. As such, the interrogation signal is emitted based on the pre-defined timing sequence. The pre-defined timing sequence may include a repeated on/off interrogation sequence, or continuously scanning interrogation sequence.

A baler implement includes a housing that defines a baling chamber for forming crop material into a bale. The baler implement further includes a knotter system having a component that is moveable between a standby position and a wrapping position while wrapping the bale. A knotter sensor communicates a knotter engagement signal in response to movement of the component. A reader is in communication with the knotter sensor and is emits an interrogation signal for reading an identification tag on the bale. The reader emits the interrogation signal for a predefined period of time in response to the knotter engagement signal from the knotter sensor indicating movement of the component of the knotter system while wrapping the bale with the strand material.

A knotter system of a baler for performing a knotter cycle including at least a first knot forming cycle and a second knot forming cycle. The knotter system includes a needle; a tucker arm; a billhook assembly including a billhook with a lower lip and an upper lip mounted pivotally with respect to lower lip; and a driver to make the billhook perform at least a first full rotation and a second full rotation. The billhook assembly is configured to position the upper lip away from the lower lip in a first angular range and to position the upper lip away from the lower lip in a second angular range of at least one of the first and second full rotation. The first angular range is located within a range between 0° and 160°, and the second angular range is located within a range between 160° and 360°.

A twine tensioner arrangement for a baler including a pair of rollers, each of the rollers being rotatable about a shaft and having circumferential lobes, at least one of the shafts being mounted on a displaceable armature, displacement measurement apparatus to measure the displacement of the displaceable armature and a signalling apparatus to generate a signal if the displacement of the displaceable armature exceeds a predetermined value. This enables monitoring of the tension in a strand of twine entering the twine tensioner arrangement and when the tension exceeds a predetermined value, allows action to be taken to avoid a mistie or damage to the baler components.