The invention relates to crop gathering apparatus for harvesting machines such as combine harvesters, and in particular to a header including a table to receive cut crop and a crop gathering mechanisms such as reels, augers and draper belts arranged across the header width and operable to convey the cut crop inwardly to an outlet disposed in a rear wall of the header.
U.S. Pat. No. 7,540,130 describes an agricultural harvesting machine having a header in the form of a centre platform section and left and right wing sections. The centre platform section has a draper belt carrying cut crop into a feeder housing of the machine, and the wing sections have lateral draper belts carrying cut crop inwardly across the header to the centre platform section. Each of the wing sections has a respective gathering reel, with each reel coupled via a universal joint to a single driven shaft extending forwardly from the feeder housing and driving a synchronised rotation of the reels. Each wing section is pivotably attached to the centre platform section, and each features a respective hydraulic cylinder coupled between the wing section and centre section. Operation of the hydraulic cylinders causes the wing sections to be controllably tilted up or down relative to the centre platform section to facilitate harvesting on uneven ground.
U.S. Pat. No. 10,813,288 describes an agricultural harvesting machine which includes a header, a feederhouse and a draper belt for transporting agricultural material to the feederhouse. The draper belt is controllable based on a distribution of crop across the header determined, for example, using potentially complex arrangements of machine mounted sensors and/or mapping data.
According to a first aspect of the present invention there is provided a harvesting header for attachment to a harvesting machine, the header comprising two or more sub-assemblies each of which includes a respective crop gathering mechanism and a respective drive mechanism coupled to operate the crop gathering mechanism, wherein the drive mechanisms for the respective sub-assemblies are operable independently of one another and in dependence on a radius of a curved path travelled by the harvesting machine.
As will be described further below, by enabling the sub-assemblies to operate independently (e.g. at different speeds), a more efficient harvesting operation with reduced tendency to clogging or blocking becomes possible. By enabling the operation of the sub-assemblies to be controlled independently in dependence on a radius of curved path travelled by an associated harvesting machine, the header may account for variations in the effective forward speed of the header across the width of the header upon turning, thereby addressing problems associated with localised blocking of the header due to differing crop input rates across the header. Such an arrangement may also provide a less complex setup when compared with prior art systems which utilise various sensor arrangements for determining characteristics of the crop forward of the harvesting machine.
The drive mechanisms for the respective sub-assemblies may be configured such that an operating speed thereof is controllable in dependence on a radius of a curved path travelled by the harvesting machine
Preferably, each crop gathering mechanism of the harvesting header includes a respective reel to gather the cut crops into a table of the header, and each crop gathering mechanism suitably further includes a respective draper belt or auger to transport the cut crops inwardly to an outlet disposed in a rear wall of the header.
Each sub-assembly may include a respective cutter bar positioned to cut crops for gathering in by the reel, and the respective cutter bars across the header may be driven independently (i.e. at differing speeds) or may be operated in unison.
The harvesting header may have just two sub-assemblies disposed with one on either side of (and arranged to feed crops into) a central outlet disposed in a rear wall of the header, or it may comprise four or more sub-assemblies, suitably arranged in a line with those in outboard positions feeding those in inboard positions en route to the outlet.
According to a further aspect of the invention there is provided a harvesting machine having mounted thereon a header as recited above, the harvesting machine comprising a control unit for controlling operation of the drive mechanisms for the respective sub-assemblies of the header in dependence on a radius of a curved path travelled by the harvesting machine.
The invention further provides a harvesting machine having mounted thereon a header as recited above, the harvesting machine being configured to provide a respective source of motive power to each sub-assembly drive mechanism, and further comprising a control unit coupled with the sources of motive power and operable to cause the crop gathering mechanisms of the sub-assemblies to operate at different speeds from one another. The drive mechanisms may be mechanical (in the form of respective driven shafts from the harvesting machine to the header) or electrical (with electric drive motors for the respective components provided in each drive sub-assembly). As will be recognised, the latter arrangement may be preferable for simplicity of control where the header comprises multiple (e.g. three or more) sub-assemblies.
Preferably, the harvesting machine further comprises a turn-detection apparatus coupled with the control unit and arranged to detect when the harvesting machine is travelling on a curved path, with the control unit configured to vary an operating speed of the respective crop gathering mechanisms in dependence on a radius of the curved path being travelled. By running the crop gathering mechanism (or mechanisms) on the outside of a curved path at a higher speed than those on the inside path, as the effective forward speed of the header will vary across the width of the header as it turns, problems of localised blocking of the header due to differing crop input rates can be greatly reduced or cancelled.
In a harvesting machine as described in the previous paragraph, the turn-detection apparatus may comprise one or more sensors connected to detect a turn angle in a steering apparatus of the harvesting machine, or may comprise a satellite-based position determination system such as GPS or GNSS.
The harvesting machine may further comprise at least one respective sensor associated with each sub-assembly, which sensors may be mounted on the harvesting machine or the header. The sensors are coupled with the control unit, and configured to detect one or more characteristics of a crop in the path ahead of the sub-assembly, and the control unit is configured to vary the operating speeds to the respective crop gathering mechanisms in dependence on variations between detected crop characteristics
Also in accordance with the present invention there is provided a method of operating the harvesting header according to the first aspect of the invention, comprising determining a path being traversed by the header during a harvesting operation; detecting when the path is a curved path; and varying an operating speed of the respective crop gathering mechanisms in dependence on a radius of the curved path being travelled.
In embodiments, localised variation in detected standing crop density immediately ahead of the different sub-assemblies of the header (or other characteristics of the crop and/or path ahead) may be used to trigger a variation in operating speed between adjacent sub-assemblies.
The invention will now be described, by way of example only, with reference to the accompanying figures in which:
The invention will now be described in the following detailed description with reference to the drawings, wherein preferred embodiments are described in detail to enable practice of the invention. Although the invention is described with reference to these specific preferred embodiments, it will be understood that the invention is not limited to these preferred embodiments. But to the contrary, the invention includes numerous alternatives, modifications and equivalents as will become apparent from consideration of the following detailed description.
Throughout the following description, the terms ‘front’, ‘rear’, ‘left’, ‘right’, ‘transverse’ and ‘longitudinal’ are used in relation to the normal forward (parallel to a longitudinal axis) direction of travel of the combine harvester 10.
With reference to
With reference also to
As in known combine headers, the header 12 may further comprise a reel 30 which guides the crop into the header with a plurality of guide bars 32, commonly six, which are mounted on (hexagonal) wheels which rotate around a transverse axis above the cutter bar 28. As particularly shown in
In the embodiment of
As shown, the header may comprise a further belt 44 in a central section between the sub-assemblies 12A, 12B. This further belt 44 operates transversely to the draper belts 42A, 42B (having received cut crop deposited by the draper belts) and carries the cut crop through the opening 34 and into the feeder housing 14 for onward handling by the processing mechanism 20.
A key feature of the present invention is that the crop gathering mechanisms (reel and draper belt or auger) of one header sub-assembly are operable independently of the (or each) other. Whilst there is suitably coordination between e.g. the reel and draper belt speeds of one sub-assembly, it is important to recognise that the separate sub-assemblies may be operated at different speeds. The benefit of this independence will become clearer when considering the different crop-loading across the header when the combine executes a turn manoeuvre: this is discussed further with reference to
In order to provide independent drive to the sub-assemblies, different options are possible. In the embodiment of
As an alternative to mechanical drive, one or more of the crop gathering components may be provided with electric drive through one or more electric motors mounted on the header and driving the components directly. This arrangement is preferred where there are e.g. four or more sub-assemblies as the control connections become simpler than having multiple mechanical drive shafts, and the (generally shorter) header sections and sub-assemblies will require less power to drive.
The ECU 56, which will typically also control other operations of the combine 10, is connected with a turn detection apparatus by means of which the combine determines whether it is travelling on a straight path, or on a curved path (and in the latter case the radius R of the turn is also determined). In the embodiment of
In
In
where Y=f(R) is determined as a function of the turn radius R.
If step 102 determines that the header 12 (or the combine carrying the header) is turning, then at step 108 the radius R of the turn is determined. Next, at step 110, an extent of variance Y to be applied between the header operating sections is determined.
Following steps 104 and 110, the individual speeds of the header sections 12A, 12B, 12C, 12D are adapted in step 112 (based on the turn radius or other characteristic) and the process returns to the start 100.
As will be recognized, the variation of header section operating speeds may take account of both turn radius and other path characteristics, in which case the two branches of
In the foregoing, the applicants have described a harvesting header 12 for attachment to a harvesting machine. The header 12 comprises two or more sub-assemblies 12A, 12B each of which includes a respective crop gathering mechanism 30, 42 and a respective drive mechanism 46, 48, 50 coupled to operate the crop gathering mechanism. The drive mechanisms for the respective sub-assemblies 12A, 12B are operable independently of one another to enable them to run at different speeds when the harvesting machine is performing a turn manoeuvre.
From reading the present disclosure, other modifications will be apparent to persons skilled in the art.
Number | Date | Country | Kind |
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1918836.6 | Dec 2019 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2020/060927 | 11/19/2020 | WO |