The invention relates to agricultural combines. More particularly it relates to methods for distributing agricultural residue over the ground.
Agricultural combines separate crop plants from the field, then separate the crop plants into a crop portion and a residue portion. The crop portion is saved within the agricultural combine for later transfer to storage facilities, and the residue portion is distributed over the ground.
Crop residue is typically chopped into short pieces before it is distributed over the ground. This chopping is performed by residue choppers that are typically constructed as a drum from which short blades are suspended. As this drum rotates the blades extending from the drum hit the stalks of the crop plant and cut them against a row of stationary blades.
Once the crop is chopped, it is thrown out the rear of the combine and is spread over the ground. Typically, a row of steering vanes are provided behind the chopper to spread the chopped plant stalks to the left and to the right of the combine.
One problem with this arrangement is the velocity of the chopped crop plants. They must have a relatively high velocity to be chopped, bounced against steering vanes, and continue onward 5-10 m to the left and to the right of the combine.
One way to improve the velocity of the chopped up plant stalks is to operate the chopper at a high rate of speed, such as 3000 RPM. Another way is to add fan blades to the chopper that will increase the air flow through the chopper, and thus blow the chopped crop plants farther away from the vehicle.
When these solutions are adopted, the chopper consumes significantly more power. Further, since it is the chopper that provides the impetus to the chopped crop plants, the chopper speed cannot be varied to control the quality of the chopping, but must operate at a very high speed in order to ensure the chopped crop plants are widely distributed.
What is needed, therefore, is a system of chopping and spreading residue that permits the chopper to operate more efficiently, and to chop more effectively, yet provide a wide distribution of chopped crop plants behind the combine. It is an object of this invention to provide such a system.
In accordance with a first aspect of the invention a system of chopping and spreading residue in an agricultural combine is provided that comprises a chopper disposed in a crop residue flow path to receive crop residue from a threshing and separating mechanism, the chopper having a rotational axis that extends horizontally and transversely to a harvesting direction of travel; a residue accelerator disposed downstream of the chopper to receive chopped residue from the chopper and to accelerate the chopped residue; a residue spreader disposed downstream of the residue accelerator to spread the chopped residue accelerated by the residue accelerator; wherein the residue accelerator further comprises an elongate drum having a rotating axis that is disposed horizontally and transversely to the harvesting direction of travel of the agricultural combine, a plurality of rings extending about the elongate drum and fixed to the elongate drum, a plurality of vanes extending between and fixed to each adjacent pair of rings, a vane extension removably fixed to each of the plurality of vanes.
Each of the plurality of rings may have a plurality of extensions extending outwardly from a central region of each said ring, and further wherein the plurality of vanes extending between and fixed to each adjacent pair of rings is fixed to the extensions.
Each ring of the plurality of rings may define a central circular hole that extends about and is fixed to an outer surface of the elongate drum.
The system may further comprise a plurality of threaded fasteners, and each vane of the plurality of vanes has a plurality of holes that are aligned with a corresponding plurality of holes in a vane extension, and the vane extension may be removably fixed to each of the plurality of vanes with at least one of the plurality of threaded fasteners, and the at least one of the plurality of threaded fasteners may extend through the aligned holes of the vanes and the vane extensions.
The chopper may comprise an elongate drum and a plurality of chopping blades attached to the elongate drum to extend outward from the elongate drum and be supported on the elongate drum to pivot with respect to the elongate drum.
The system may further comprise a first pulley fixed to the elongate drum of the residue accelerator to drive the elongate drum of the residue accelerator in rotation; a second pulley fixed to the elongate drum of the chopper to drive the elongate drum of the chopper in rotation; and an endless belt extending around and coupling the first pulley and the second pulley, wherein the second pulley drives the first pulley in rotation.
The first pulley may have a smaller diameter than the second pulley, and the endless belt may drive the first pulley at a higher rotational speed than the second pulley.
In accordance with another aspect of the invention, an agricultural combine may comprise a threshing system, a separating system, and a cleaning system for separating grain from crop residue, and also a system for chopping and spreading that residue in accordance with claim 1.
Referring to the Figures, an agricultural combine 100 comprises a chassis 10 supported by wheels 12. The agricultural combine 100 further comprises a feeder house 14 to which an agricultural harvesting head 16 may be attached. The feeder house is a generally rectangular box that contains a crop elevator (not shown). The crop elevator carries the crop to an accelerator drum 18, which further conveys cut crop into a threshing, separating, and cleaning system. The threshing and separating system comprise a rotor 20 disposed inside a concave 22. Crop is introduced between the rotor and the concave by the accelerator drum. The forward portion of the rotor and concave function to thresh the crop between them. The rear portion of the rotor and concave function to separate the now-threshed crop from the material other than grain (a.k.a. MOG or crop residue). The grain falls downward through apertures in the concave and into a cleaning system 24 which includes sieves and/or chaffers to further separate the grain from light crop residue particles. Once clean, the grain is lifted with a crop elevator 26 and deposited into a grain tank 28 from which it is later unloaded through an unloading auger 30.
Crop residue that is separated from the grain is carried rearward through the gap between the rotor 20 and the concave 22. The crop residue is eventually released from between the rotor and concave and falls downward into a system of chopping and spreading residue 32.
The system of chopping and spreading residue 32 comprises a chopper 102 and a residue accelerator 104 at the rear of the agricultural combine. The chopper is disposed to receive crop residue released from between the rotor 20 and the concave 22, to chop that residue into smaller portions, and to convey the chopped residue to the residue accelerator 104 which is located behind (downstream) of the chopper 102.
The system of chopping and spreading residue 32 also includes a crop spreader 112, shown herein as downwardly extending vanes attached to a generally planar and horizontal base plate 113 in a fan pattern. The crop spreader 112 is disposed behind the residue accelerator 104 to steer the chopped crop residue leaving the residue accelerator 104 into a broad fanlike pattern behind the combine.
The chopper 102 comprises an elongate drum 106 that extends transverse to the direction of travel of the agricultural combine and parallel to the ground, and several blades 108 attached to the drum (see, e.g.,
The residue accelerator 104 is disposed behind and downstream of the chopper 102 to receive the chopped crop residue from the chopper 102, and to accelerate it.
The residue accelerator comprises a rotor 114 disposed in a housing, the rotor comprising an elongate drum 118 that is disposed generally parallel to the chopper drum 106. The elongate drum 118 is supported on bearings (not shown) that constrain the elongate drum 118 to rotate about a longitudinal axis 119 of the elongate drum 118. The longitudinal axis 119 is parallel to the longitudinal axis 107.
Several rings 120 are fixed to the surface of the elongate drum 118. These rings are spaced apart at regular intervals along the length of the elongate drum. Each ring 120 is generally planar and defines a plane that is perpendicular to the longitudinal rotational axis 119 of the elongate drum 118. Each ring 120 has a circular central hole that is welded to the outer surface of the elongate drum 118 and through which central hole the elongate drum 118 passes. The outer extent of each ring 120 defines a plurality of extensions 121 (five extensions are illustrated in the figures herein) that extend outward from a central region of each ring 120. Each of these extensions 121 define an elongate slot 123. The elongate slot 123 extends radially outward from the outer surface of the elongate drum 118. The longitudinal extent of the elongate slot 123 is parallel to a radial line extending outward from the longitudinal rotational axis 119.
Referring to
Each vane 122 is in the form of a planar plate that extends generally parallel to the longitudinal axis 119 and radially outward from the longitudinal axis 119.
Each vane 122 has a root portion 125 having an edge that extends generally parallel to the longitudinal axis 119, that abuts the outer surface of the elongate drum 118 and that is fixed (preferably by welding) thereto.
Thus, each vane 122 is therefore directly secured both to the elongate drum 118 and to the two rings 120 which it abuts.
Each vane 122 is provided with holes 127 that receive threaded fasteners 129 (see
In a preferred arrangement, adjacent rings 120 are fixed to the elongate drum 118 such that one ring 120 is slightly angularly offset about the longitudinal axis 119 to a different angular position about the longitudinal axis 119. When the vanes 122 are attached to two adjacent rings 120 that are angularly offset in this manner, the vane 122 itself (see, e.g.,
Referring to
Each threaded fastener 129 that secure the vane extensions 124 to the vanes 122 includes a bolt (preferably a rounded head stove bolt as shown in
The residue accelerator housing is made of a first sheet metal panel 126 that extends around and encloses the upwardly facing portion of the rotor, and a second sheet metal panel 128 that extends around and encloses the downwardly facing portion of the rotor. A forward-facing gap between the first and second sheet metal panels defines an inlet of the residue accelerator, and a rearwardly facing gap between the first and second sheet metal panels defines an outlet of the residue accelerator. The residue accelerator rotor is driven in rotation such that chopped crop material is received in the inlet, is pulled underneath the rotor, and is ejected rearwardly through the outlet of the residue accelerator.
The residue accelerator is driven by a first pulley 130 fixed to one end of the elongate drum of the residue accelerator 104. A second pulley 132 is mounted to one end of the elongate drum of the chopper 102. An endless belt 134 is wrapped around these pulleys such that they are driven by a common power source (e.g. an engine, motor, or other rotating device). The two pulleys 130, 132, as shown in the attached figures have different diameters. Thus, they are driven at different rotational speeds.
The pulley 130 attached to the residue accelerator has a smaller diameter than the pulley 132 attached to the chopper 102. The residue accelerator 104 therefore rotates at a higher speed than the chopper 102. This enables the residue accelerator 104 to operate at a higher speed to accelerate the chopped material past the steering vanes of the crop spreader 112 and out the back of the combine, while permitting the chopper 102 to operate at a lower speed. This permits the chopper 102 to operate at a slower, more efficient, less power consuming speed than conventionally, while the residue accelerator 104 operates at a higher speed to accelerate the cut crop material at the rear of the combine. In this manner, the chopper 102 can be operated at a rotational speed that chops most efficiently (and cuts the MOG to a proper chopped length) and the residue accelerator 104 can be operated at a different speed that moves the chopped crop residue most efficiently. The net result is a reduction in power consumption, better spread of chopped crop residue, and better quality of chopped crop residue.
This document claims priority and the benefit of the filing date based on U.S. provisional application No. 62/219,821, filed Sep. 17, 2015 under 35 U.S.C. §119 (e), where the provisional application is hereby incorporated by reference herein.
Number | Date | Country | |
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62219821 | Sep 2015 | US |