Dual tine paths from different tine bars in a pickup

An improved tine reel for a round baler pickup unit that allows tine position to be altered dependant of rotational position of the tine reel and the lateral position of the tine on the pickup. A plurality of tine bars are mounted on the tine reel, with separate tine bars provided for the centrally located tines and the outboard located tines. Separate cams control rotation of the centrally located inboard tine bars and the outwardly located outboard tine bars so that outboard tine position can be optimized without limitation by the inboard tines.

BACKGROUND OF THE INVENTION

The present invention relates generally to a baler for forming cylindrical bales of crop material, commonly referred to as a round baler, and more particularly to an improvement in a crop pickup apparatus for a round baler having lateral converging apparatus working in conjunction with the pickup that is wider than the bale forming chamber inlet.

Round balers rely on a pickup apparatus with a set of tines that engage a windrow of crop material on the ground and lift it upwardly and then urge it rearwardly to a transverse infeed opening into a bale-forming chamber. Pressure to increase efficiency in crop packaging operations has resulted in the prevalence of crop pickup units that are significantly wider than the bale forming chamber into which the crop material is fed. A wider pickup allows the baler to handle wider crop windrows and also results in better crop fill at the lateral extremes of the resultant bale. Historically, wide pickups have incorporated augers situated at the extremes of the pickup width to converge the crop laterally inwardly to achieve a width of the crop mat being fed into the bale chamber that is approximately the same as the chamber width. Longitudinal placement of the converging augers requires an elongated feed table, increasing the distance the crop must travel between the pickup tines and the bale chamber inlet opening. A secondary feed mechanism, such as a stuffer or rotor, is often necessary to convey the converged crop mat along the lengthened feed table and into the bale chamber.

Although quite effective, secondary feed mechanisms add complexity and cost. Without them, the potential for clogging the bale chamber infeed opening increases. Efforts to eliminate the secondary feed mechanism have focused on minimizing the distance between the pickup tines and the crop inlet opening. Reducing the feed table length to eliminate the need for a secondary feed mechanism requires that tine movement on the tine reel be optimized for maximum crop movement efficiency and to reposition tines depending on rotational position to prevent their contacting the more closely positioned converging augers. While this approach reduces the need for a secondary feed mechanism, the benefit may be offset by the increased complexity in the tine position management mechanism within the pickup apparatus.

It would be a great advantage to provide a simple tine position management mechanism for a round baler pickup unit that eliminates the need for a secondary pickup feed mechanism, reduces the required clearance between a tine reel and one or more crop converging augers to overcome the above problems and limitations.

SUMMARY OF THE INVENTION

Accordingly, the present invention, in any of the embodiments described herein, may provide one or more of the following advantages:

It is an object of the present invention to provide a variable position tine reel for a pickup unit on a round baler that extends tines situated ahead of a bale chamber inlet as far as possible toward the bale chamber inlet to enhance crop movement toward the inlet opening.

It is a further object of the present invention to provide a variable position tine reel for a pickup unit on a round baler that retracts the tines forwardly adjacent to outboard converging augers disposed on the pickup unit as far as possible to clear the augers and allow auger diameter to be maximized.

It is a further object of the present invention to provide a variable position tine reel for a pickup unit on a round baler that enables tine extension for laterally central tine positions as well as laterally outboard tine positions to be specifically optimized to improve crop flow at the transition between the crop converging augers and the floor roll situated in the crop inlet opening and reduce the likelihood of plugging.

It is a still further object of the present invention to provide a variable tine position tine reel for a pickup unit on a round baler that enables tine extension for laterally central tine positions to be varied independently from tine extension of the laterally outboard tine positions for improved crop flow at the transition between the crop converging augers and the floor roll situated in the crop inlet opening and reduce the likelihood of plugging.

It is a still further object of the present invention to provide a variable position tine reel for a pickup unit on a round baler that is light in weight to improve the ground-following capabilities of the pickup unit.

It is a still further object of the present invention to provide a variable tine position tine reel for a round baler that is durable in construction, inexpensive of manufacture, carefree of maintenance, easily assembled, and simple and effective to use.

These and other objects are achieved by providing an improved tine reel for a round baler pickup unit that allows tine position to be altered dependant of rotational position of the tine reel and the lateral position of the tine on the pickup. A plurality of tine bars are mounted on the tine reel, with separate tine bars provided for the centrally located tines and the outboard located tines. A linkage connects the centrally located inboard tine bars to the outboard tine bars so that rotation of the outboard tine bars by a tine reel cam and cam follower mechanism is transferred to the inboard tine bar without the need for a second cam or second cam follower mechanism. The linkage configuration is adjusted to provide optimal tine extension position for both the centrally located and the outboard located tines.

DESCRIPTION OF THE PREFERRED EMBODIMENT(S)

Many of the fastening, connection, processes and other means and components utilized in this invention are widely known and used in the field of the invention described, and their exact nature or type is not necessary for an understanding and use of the invention by a person skilled in the art, and they will not therefore be discussed in significant detail. Also, any reference herein to the terms “left” or “right” are used as a matter of mere convenience, and are determined by standing at the rear of the machine facing in its normal direction of travel. Likewise, “forward” and “rearward” are determined by the normal direction of travel. “Upward” and “downward” orientations are relative to the ground or operating surface as are any references to “horizontal” or “vertical” planes. Furthermore, the various components shown or described herein for any specific application of this invention can be varied or altered as anticipated by this invention and the practice of a specific application of any element may already be widely known or used in the art by persons skilled in the art and each will likewise not therefore be discussed in significant detail. When referring to the figures, like parts are numbered the same in all of the figures.

FIG. 1illustrates a conventional crop pickup assembly10for a round baler. During field operation, the pickup assembly picks up crop material, such as hay, from the ground and feeds it into a fixed or adjustable chamber on the baler where it is rolled up to form a compact cylindrical package of hay. While still inside the chamber, the formed package is wrapped in its compact form by net, twine, or the like, prior to being ejected as a bale onto the ground for subsequent handling. The operation of pickups and round balers is well-known and is shown by way of example in U.S. Pat. No. 5,044,272, issued on Sep. 3, 1991 to Richard E. Jennings, the entirety of which is incorporated herein by reference.

In baler applications where the pickup assembly10is wider than the inlet opening90, a crop converging apparatus30is typically provided to laterally urge crop from the portions of the pickup assembly outboard of the inlet opening inwardly toward the inlet opening90of the bale chamber, shown as the inboard feed area inFIGS. 1 and 2. The converging apparatus30urges crop material laterally inwardly to establish a mat of crop material having a width matching that of the inlet opening90and desired bale width, typically around four or five feet. In the embodiment shown herein, the converging apparatus30comprises a pair of augers31arranged on opposing outboard ends of the crop pickup assembly.

Now referring toFIGS. 1 through 3, a first embodiment of the pickup assembly10is shown to include a plurality of pick up tines24connected to a rotating tine reel20which engages and lifts crop material from the ground to an upper surface of the pickup assembly, referred to as the feed table16, for rearward movement toward the inlet opening90to bale chamber, vertically bounded by floor roll71and starter roll72and laterally bounded by the side walls of the bale forming chamber. The tines24are connected to a plurality of tine bars22, which are in turn connected to the tine reel20by a pair of outboard tine spiders25a,25b, and one or more inboard tine spiders28. The elongate tine bars22are aligned parallel to tine reel axis100and radially spaced-apart therefrom. The tine spiders25a,25b,28are configured to rotate in unison around tine reel axis100in the direction shown when powered by a drive mechanism in the baler thereby causing the tine bars22to revolve or orbit about the reel axis100. As the tine reel20revolves, individual tine bars22may be rotated to vary the angle at which the tines24extend from the tine bars22. Tine bar rotation is accomplished by the inclusion of one or more cam followers26a,26bengaging a first cam90aor a second cam90band connected to the tine bars22in a manner to rotate the tine bars22as the tine reel20revolves in order to alter the angle of the tines24. Tine positioning is desirable to improve crop pickup from the ground, to accelerate the crop material, and to provide clearance between the tines and closely positioned portions of the baler or pickup assembly.

The tine reel20is laterally configured into three adjacent zones: an inboard feed area and two outboard feed areas (seeFIGS. 1 and 2). The inboard feed area is located immediately ahead of the floor roll71. The inboard feed area is laterally bounded on each side by an outboard feed area, each outboard feed area being located immediately ahead of the converging augers31. Tine reel20is configured to produce optimal tine orientation for the inboard feed area and the outboard feed areas, even though optimal movement requires different tine movement and timing. Due to the relative differences in proximity of the tine reel to the floor roll71and the converging augers31, the tips of the inboard tines24iand the outboard tines24omust travel slightly different paths. Tine reel20thus comprises a plurality of inboard tine bars22iwhich are positioned generally parallel to and spaced about the tine reel axis100. Tine reel20further comprises a plurality of outboard tine bars22o, each angularly displaced relative to a respective inboard tine bar22i, each also aligned generally parallel to the tine reel axis100. Each inboard and outboard tine bar22i,22ois connected to the spiders25a,25b,28by one or more bearings80which allows the tine bars22to rotate about a respective tine bar axis102,103. Inboard and outboard tine bars22i,220are displaced from the tine reel axis by a radius R, which may be the same for the inboard tine bars22iand the outboard tine bars22o. Alternatively, the outboard and inboard tine bars22o,22imay be radially displaced from the tine reel axis at different distances to further improve outboard tine24oclearance with the converging augers31.

Each inboard tine bar22iincludes a cam link27aand a cam follower28aconnected at one end and configured to engage an inboard cam90ain a manner to control rotational movement of the tine bar22ias the tine reel20revolves around the tine reel axis100. Rotation of the inboard tine bars22iallows the angular extension of the inboard tines24ito be altered as the tine reel revolves. The profile of inboard cam90ais configured to produce optimal inboard tine24imovement at all positions of the tine reel revolution for effectively conveying crop material from the pickup to the bale chamber inlet. The use of a unique cam profile for the inboard tines24ienables optimal tine movement without limitations or compromises required when a single cam profile is used to control both inboard and outboard tines. Inboard tine bars22imay extend the entire transverse width of the tine reel20or they may be shortened to span from an outboard end of the tine reel at which the inboard cam90ais located to a position spanning at least the inboard feed area.

Similarly, each outboard tine bar22oincludes a cam link27band a cam follower28bconnected at one end and configured to engage an outboard cam90bin a manner to control rotational movement of the outboard tine bar22oas the tine reel20revolves around the tine reel axis100. Rotation of the outboard tine bars22oallows the angular extension of the outboard tines24oto be altered as the tine reel revolves. The profile of outboard cam90bis configured to produce optimal outboard tine movement at all positions of the tine reel revolution for effectively conveying crop material from the pickup to the bale chamber inlet while preventing contact between the outboard tine and the converging augers31. Outboard tine bars22opreferably extend the entire transverse width of the tine reel20in tine reels having two outboard feed areas, one at each end of the tine reel. Outboard tines24oare only connected to the outboard tine bars22oin the portions of the tine reel width immediately adjacent to the converging augers31.

A second embodiment is shown inFIGS. 4 and 5, wherein the inboard tine bars22iand outboard tine bars22oare shortened so that they do not extend the entire transverse width of the tine reel20. The tine reel thus comprises opposing end spiders25a,25b, first, second, and third intermediate spiders48,58,68, respectively configured to rotate in unison around tine reel axis100. Right outboard tine bars22oR and left outboard tine bars22oL are rotatably mounted to respective spiders, each including one end spider25, connected by bearings80. As presented the right end outboard tine bars22oR are connected to end spider25aand third intermediate spider68. The left end outboard tine bars22oL are connected to end spider25band first intermediate spider48. Though not shown, additional spiders28may be positioned between the end spiders and the respective intermediate spiders to increase reel stability.

Each outboard tine bar is provided with a cam link27bR,27bL and a cam follower26bR,26bL connected at the outboard end of the tine bar adjacent to the respective end spider. The cam followers26bR,26bL engage respective outboard cams90bR,90bL in a manner to control rotational movement of the right and left end outboard tine bars22oR,22oL as the tine reel20revolves around the tine reel axis100to control the angular extension of the outboard tines24o. The inclusion of individual cams90bR,90bL for outboard tine bars on each end of the tine reel allows the portion of the tine bar spanning between the outboard ends to be eliminated, reducing overall tine reel weight. The cam profiles for the outboard cams90bR,90bL are preferably similar so that outboard tine movement is symmetric between the outboard feed areas of the pickup and optimized for crop conveyance and avoidance of the converging augers31.

Each inboard tine bar22iis supported by bearings80connected to first intermediate spider48and second intermediate spider58for revolution with the tine reel assembly20about tine reel axis100. Each inboard tine bar22iis also provided with a cam link27aand a cam follower26aconnected at one end of the inboard tine bar22i. The cam followers26aengage inboard cam90ato control rotational position of the inboard tine bars22ias the tine reel revolves. In the second embodiment, inboard cam90ais disposed between the tine reel ends at a position adjacent to one of the inboard/outboard feed area transitions. The profile of inboard cam90ais optimized for inboard tine movement without regard to the outboard tine movement limitations which thereby enables optimal crop conveyance toward the bale chamber inlet. As with the outboard tine bars, the inboard tine bars22ineed not span the entire transverse width of the tine reel; their length may be limited to the width of the inboard feed area. Limiting the length of the tine bars in the reel offsets the weight of the additional cam and linkages and enables the overall crop pickup weight to be maintained within reasonable limits.

An additional advantage in the second embodiment shown inFIGS. 4 and 5is that the inboard and outboard tine bars22i,22omay be arranged on a common axis (wherein tine bar axes102and103are the same axis). This arrangement reduces the peripheral space necessary for a complete transverse array of tines compared to angularaly offset inboard and outboard tine bar arrangements and may allow the number of tine bars to be increased.FIG. 5illustrates a four-bar tine reel; however, due to the space-saving nature of aligning the inboard and outboard tine bars on a common axis, the same tine control apparatus may be expanded to a five- or six-bar tine reel.

FIG. 6illustrates typical variations between inboard tine paths (shown as tine path110i) and outboard tine paths (shown as tine path110o). Rather than requiring all tines to have the same general path shape offset rotationally as is required when using a single cam, the figure illustrates the advantages of providing unique cam profiles for the inboard tines and the outboard tines so that the tine paths for each may be individually optimized.