Rotary Tedder

Abstract

An agricultural implement includes a main frame attachable to a towing vehicle, a wheel support supporting the main frame and having main wheels, and a lifting unit configured to bring the agricultural implement into one of a transport position, a working position, or a headland position. The wheel support and the tedder frame are each pivotable around a common axle on the main frame, the lifting unit includes an adjustment assembly attached to the wheel support at a first attachment point and to the tedder frame at a second attachment point, the first attachment point and the second attachment point span the common axle and form a triangle therewith, and the lifting unit is configured to pivot the tedder frame and the wheel support around the common axle to bring the agricultural implement into a predetermined position between and including the working position and the headland position.

Claims

1. An agricultural implement, comprising: a main frame attachable to a towing vehicle; a wheel support supporting the main frame and having a plurality of main wheels; a plurality of tedder units supported on a tedder frame, the plurality of tedder units each having a plurality of tines; and a lifting unit configured to bring the agricultural implement into one of a transport position, a working position, or a headland position; wherein the wheel support and the tedder frame are separate elements, each pivotable around a common axle on the main frame; wherein the lifting unit comprises an adjustment assembly, the adjustment assembly being attached to the wheel support at a first attachment point and to the tedder frame at a second attachment point, the first attachment point and the second attachment point spanning the common axle and forming a triangle therewith; wherein the lifting unit further comprises a guide on the tedder frame; and wherein the lifting unit is configured to pivot the tedder frame and the wheel support around the common axle to bring the agricultural implement into a predetermined position between the working position and the headland position.

2. The agricultural implement of claim 1, wherein the predetermined position between the working position and the headland position includes a position in which the plurality of tines of the plurality of tedder units are lifted above ground and in which tedder wheels of the plurality of tedder units remain on the ground.

3. The agricultural implement of claim 1, wherein the tedder frame comprises a guiding portion having a long hole as the guide.

4. The agricultural implement of claim 1, wherein the adjustment assembly is configured to adjust a relative position of the wheel support with respect to the tedder frame.

5. The agricultural implement of claim 1, comprising at least one central actuator connected with the guide on the tedder frame, wherein the at least one central actuator is configured to bring the agricultural implement into and out of the transport position.

6. The agricultural implement of claim 5, wherein the least one central actuator is configured to pivot the lifting unit around the common axle while keeping a relative position of the wheel support with respect to the tedder frame unchanged.

7. The agricultural implement of claim 1, wherein the adjustment assembly comprises a hydraulic actuator, a manual spindle, or a combination thereof.

8. The agricultural implement of claim 5, wherein the at least one central actuator comprises one or more hydraulic actuators.

9. The agricultural implement of claim 5, wherein the adjustment assembly, the at least one central actuator, or a combination thereof, is configured to be remotely controlled by the towing vehicle.

10. The agricultural implement of claim 1, comprising a sensor configured to sense positions of the plurality of tedder units, a ground clearance of at least one of the plurality of tedder units, or a combination thereof.

11. The agricultural implement of claim 1, comprising a sensor configured to sense positions of the plurality of main wheels, a ground clearance of the common axle, or a combination thereof.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0018] FIG. 1 is a side view of a preferred embodiment of the agricultural implement according to the invention in the working position;

[0019] FIG. 2 is a detailed side view of the main components shown in the embodiment of FIG. 1;

[0020] FIG. 3 is a detailed side view of the main components in FIG. 1 in an intermediary position;

[0021] FIG. 4 is a detailed side view of the main components in FIG. 1 in a headland position; and

[0022] FIG. 5 is a detailed side view of the main components in FIG. 1 in a transport position;

DETAILED DESCRIPTION OF SPECIFIC EMBODIMENTS

[0023] FIGS. 1 and 2 show a side view of a preferred embodiment of the agricultural implement according to the invention in the working position. The agricultural implement may be a tedder 1 having a main frame 3 which can comprise on one end a tow hook or tow ring 2 configured to engage with the tow hitch of a towing vehicle (not shown) and on the other end a common axle 5 configured for attaching a wheel chassis and a plurality of tedder units as will be explained below. Between the two ends a mounting portion 4 may be provided at which at least one central actuator may be attached which will also be explained in detail below.

[0024] In this embodiment, two components may be pivotably attached to the common axle 5: a wheel support 6 having a main wheel 7 rotatably attached on either side of the agricultural implement 1, and the tedder frame 8 to which the plurality of tedder units 10 may be attached. Each tedder unit 10 may essentially comprise a rotary rake 11 having a plurality of forks or tines 12 which are configured to move, swath or otherwise distribute freshly cut hay or other crop on a field. The plurality of tedder units 10 may in the present embodiment be distributed on the tedder frame 8 transversely to the driving direction of the agricultural implement one such that on either side of the main frame 3 an equal number of tedder units 10 covers an area as wide as possible. In the transverse direction, the tedder frame 8 may comprise side portions, hinges and drives which are configured to enable a folding of tedder units 10 onto the tedder frame 8 and to supply energy to drive the rotary rakes 11. Furthermore, a plurality of tedder wheels 13 may be positioned along the width of the tedder frame 8, preferably one tedder wheel 13 per tedder unit 10.

[0025] The drive for rotatably driving the rotary rakes 11 may, for example, be designed with drive shafts which are propelled by the PTO of the towing unit.

[0026] In the working position shown in FIG. 1, the side parts of the tedder frame 8 are fully extended and articulated in such a way that ground surface inequalities such as bumps and the like may be compensated. In addition to the pivoting motion of the side portions of the tedder frame 8, the tedder units have a further degree of freedom by rotating the tedder frame 8 in relatively small ranges around the common axle 5.

[0027] To this end, the wheel support 6 and the tedder frame 8 are advantageously connected in a common axle 5 as mentioned above. Furthermore, those two components are connected by an adjustment assembly which is located between a first attachment point on the wheel support 6 and a second attachment point on the tedder frame 8. In the shown embodiment, the first attachment point may be a first pivot axis 14 which is attached to the wheel support 6 at a central portion thereof, and the second attachment point may be a second pivot axis 15 located on an attachment portion of the tedder frame 8 which is positioned towards the common axle 5. Arranged between the first pivot axis 14 and the second pivot axis 15 may be a rod having a first adjustment actuator 16 and a second adjustment actuator 17, all these elements thereby forming the adjustment assembly in this embodiment. In the present embodiment, the first adjustment actuator 16 may be a hydraulic cylinder 16 and the second adjustment actuator 17 may be a manual spindle apparatus 17. The hydraulic cylinder 16 may be powered by a hydraulic line connected with the towing vehicle.

[0028] The first and second adjustment actuators 16, 17 together with the rod form the adjustment assembly also as a part of a lifting unit which is configured to set and/or adjust the relative position of the wheel support 6 with respect to the tedder frame 8. In other words, the setting of the adjustment actuators determines the length or distance between the first pivot axis 14 and the second pivot axis 15 such that the wheel frame 6 and the tedder frame 8 form a rigid unit acting like a boogie chassis which may pivot around the common axle 5. It is understood that when the distance between the first pivot axis 14 and the second pivot axis 15 is shortened and the relative position between the main frame 3 and the wheel support 6 is not changed, then the tedder frame 8 pivots slightly around the common axle 5 such that its free portion is lifted relative to the wheel support 6 having the wheels 7 which rest on the ground surface.

[0029] However, the movement of the tedder frame 8 triggered by operating one or more of the at least one adjustment actuator 16, 17 is limited by a structure which is a part of the tedder frame 8: a guiding portion 18 may be included in the tedder frame 8 at the free and opposite of the tedder units 10, the guiding portion 18 being configured to guide and limit the movement of the tedder frame 8 by being connected to at least one central actuator. It is noted that the guiding portion 18 may be integral with the tedder frame 8 or may be a separate component attached to the tedder frame.

[0030] In the shown embodiment, the at least one central actuator may comprise a first central actuator 20 and a second central actuator 21 both acting on a rod extending between the mounting portion 4 of the main frame 3 and the guiding portion 18 of tedder frame 8. In other embodiments, the at least one central actuator may include a single central actuator, preferably a hydraulic cylinder which, in combination with a position detection unit, can be actuated as needed.

[0031] A long hole 19 may be arranged as part of the guiding portion 18 wherein a guiding pin 22 formed on one and of the rod is accommodated within the long hole 19. Therefore, the movement of the tedder frame 8 is restricted by the movement of the guiding pin 22 within the long hole 19. This limitation of movement has several effects which will be explained below.

[0032] A first, predetermined movement of the guiding pin 22 within the long hole 19 is achieved by changing the extension of any of the adjustment actuators 16, 17 or central actuators 20, 21. As mentioned above, the predetermined movement of the second adjustment actuator 17 which may be a manual spindle handled by the operator of the implement effects an adjustment of the height of the tines 12 of every tedder unit 10. Looking at FIG. 2, for example, extending the length between the first pivot axis 14 and the second pivot axis 15 will lift the tines 12 of every tedder unit 10 on the forward side of the tedder wheel 13, i.e. where the times 12 are intended to engage with the crop lying on the ground surface. In a similar fashion, decreasing the length between the first pivot axis 14 and the second pivot axis 15 will move the tines 12 of the tedder units 10 between the main wheel 7 and the tedder wheel 13 closer to the ground surface, i.e. the angle of the plane of rotation of the tedder units 10 with respect to the ground surface will increase.

[0033] On the other hand, a second, independent movement of the entire wheel support/tedder frame combination may occur when the agricultural implement 1 is pulled over an even ground surface. For example, the main wheel 7 may impinge on a stone or rock on the ground surface such that it is slightly lifted. As there is a rigid, boogie-like structure consisting of the wheel support 6 having the main wheel 7 and the tedder frame 8 having the tedder units 10 with the tedder wheels 13, the lifting of the main wheel 7 will effect a pivoting movement of the rigid structure about the common axle 5. This is enabled by the limited, but possible movement of the guiding pin 22 within the long hole 19. Within the range of travel of the guiding pin 22 in the long hole 19 there is thus a possibility of a tilting movement of the boogie-like structure such that uneven ground surface passages may be compensated without exerting any forces on the main frame 3.

[0034] FIG. 3 shows a side view of the embodiment of FIGS. 1 and 2 in an intermediary position where the times 12 of the tedder units 10 have been lifted above the ground surface. This predetermined or intermediary position was achieved by extending the distance between the first pivot axis 14 and the second pivot axis 15 by means of the first adjustment actuator 16 and/or the second adjustment actuator 17 of the adjustment assembly. It can clearly be seen in FIG. 3 that the guiding pin 22 within the long hole 19 has reached a first stop position which is the leftmost position in the shown embodiment. Further, the angle between the wheel support 6 and the tedder frame 8 has changed accordingly bringing the main wheel 7 and the tedder wheels 13 slightly closer together. It should be mentioned that in this position, it is no longer possible to extend the distance determined by the adjustment actuators because the guiding pin 22 within the long hole 19 is already in its stop position. However, in other embodiments pin 22 may not be in this stop position when the at least one actuator is extended.

[0035] The headland position of the agricultural implement 1 is shown in a side view of FIG. 4. Starting from the intermediary position of FIG. 3, the central actuators 20, 21 or only the central actuator 20 were actuated so as to decrease the length of the rod on which they are located. This causes the tedder frame 8 including the tedder units 10 and the wheel support 6 to be pulled towards the towing unit. As the wheel support and the tedder frame 8 are pivotably attached to the main frame 3 at the common axle 5 the pulling movement of the central actuators 20, 21 effects a pivoting movement of the entire boogie-like structure lifting the tedder wheels 13 from the ground surface. FIG. 4 shows that the angle between the wheel support 6 and the tedder frame 8 remains constant with respect to the intermediary position shown in FIG. 3 but the respective position of the central actuators has changed. In this position, the agricultural implement one can be safely moved in a headland turn such that none of the tedder units 10 may engage with the ground surface. As seen in FIGS. 3 and 4, the height of the tedder units 10 above the ground surface is determined by the adjustment actuators 16, 17 as well as the central actuators 20, 21.

[0036] In FIG. 5, the agricultural implement 1 is shown in the transport position. This position starts from the headland position, shown in FIG. 4, in which hydraulic cylinders or other actuators firstly fold the side portions (not shown) of the tedder frame 8 onto one another so that the overall with of the agricultural implement 1 will not exceed its allowed value in the transport position. Then, the central actuator(s) 20, 21 may be actuated, for example by moving the hydraulic cylinder(s) of the actuator(s) to its/their shortest length. This will further pull the tedder unit portion of tedder frame 8 and causes a further rotational movement of the boogie-like structure around common axle 5 thereby further lifting the tedder units 10 to their substantially full vertical extension in which the rotary rakes are orientated perpendicular to the ground surface. It should be noted that also here, as also shown in the headland position of FIG. 4, the vertical position of the common axle 5 is also slightly lifted due to the length of the wheel frame 6. It can also be seen that the long hole 19 is now orientated vertically, i.e. essentially perpendicular to the central actuators 20, 21. This has the technical effect of locking the tedder frame 8 rigid to main frame 3.

[0037] It is understood that moving from the transport position into any of the other positions follows the reverse order of movement of the respective actuators.