Planting assembly and machine

Abstract

A planting machine for forming a trench for planting seeds and/or fertilizer in a ground surface, including a frame that supports a planting assembly having a cutting tool and a gauge that sets the height of the cutting tool so as to determine a depth of the trench formed by the tool, wherein the assembly includes a linkage coupled between the frame to the gauge and an actuator to allow for remote adjustment of the linkage, in order to vary a planting depth of the trench.

Claims

1. A planting machine for forming a trench for planting seeds and/or fertilizer in a ground surface, comprising: a frame that supports a planting assembly having a cutting tool and a gauge that sets the height of the cutting tool so as to determine a depth of the trench formed by the tool, wherein the planting assembly includes a linkage coupled between the frame and the gauge and an actuator to allow for remote adjustment of the linkage, in order to vary a planting depth of the trench, wherein the gauge and the cutting tool are mounted to the frame with a parallelogram coupling and the linkage is mounted directly to the parallelogram coupling and adapted to raise and lower the gauge relative to the parallelogram coupling, wherein the machine includes a plurality of planting assemblies, each with a respective tool, gauge, linkage and actuator, wherein various ones of the actuators are mechanically linked to operate in unison, and wherein the planting assemblies are arranged in a series of ranks, positioned one behind the other, the ranks being mechanically connected with fore and aft extending links, pivotally connected to each of the respective actuators.

2. The planting machine of claim 1, wherein the linkage is pivotally mounted to the coupling to move in unison with the coupling.

3. The planting machine of claim 2, wherein the linkage forms a pantograph connector to match movement between the linkage and the coupling.

4. The planting machine of claim 1, wherein the gauge and tool are mounted to a connecting section of the parallelogram coupling, with the cutting tool being fixed to the connecting section by a connecting arm and the gauge being pivotally mounted to the connecting section by a pivoting arm and wherein the linkage is coupled to the pivoting arm so that rotation of the actuator changes the orientation of the arm relative to the coupling, via the linkage, to lift and lower the arm to thereby change the relative height of the gauge and cutting tool in order to adjust the planting depth.

5. The planting machine of claim 4, wherein the gauge is in the form of a ground engaging gauge wheel offset from the tool along the extent of the arm, wherein the linkage is coupled to the arm to lift and lower the arm to thereby modify the relative height between the gauge wheel and the tool.

6. The planting machine of claim 1, wherein the planting assembly further includes a delivery boot positioned adjacent the cutting tool, for depositing seed or fertilizer in the trench cut by the cutting tool and wherein the cutting tool is in the form of one or a combination of a disc, tine, point or point sweep.

7. The planting machine of claim 1, wherein multiple planting assemblies are provided in each rank and lateral links couple the actuators of each rank to the associated fore and aft extending links.

8. The planting machine of claim 1, wherein the machine includes a hydraulic cylinder for driving the fore and aft extending links in a fore and aft direction, wherein the cylinder is arranged to be remotely controlled from a cabin of a vehicle towing the planting machine.

9. The planting machine of claim 1, including a plurality of frames across the width of the machine and an associated set of multiple planting assemblies for each frame.

10. The planting machine of claim 1, further including multiple phased cylinders for adjusting the planting depth of each of the assemblies in unison.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention is described, by way of non-limiting example only, with reference to the accompanying drawings, in which:

(2) FIG. 1 is a side view of a prior art seeding assembly;

(3) FIG. 2 is a side view of a planting machine;

(4) FIG. 3 is a side view of the machine of FIG. 2 with a planting assembly in a downward position;

(5) FIG. 4 is a side view of the machine with the planting assembly in an upward position;

(6) FIG. 5 is a side view of the machine with a press wheel biasing mechanism in the form of a cylinder;

(7) FIG. 6 is a view of the machine from an opposite side;

(8) FIG. 7 is a side view of the machine with a series of ranks or planter assemblies;

(9) FIG. 8 is a perspective view of the arrangement of ranks within a first frame structure of the machine;

(10) FIG. 9 illustrates a second frame structure of the machine;

(11) FIG. 10 is a perspective view illustrating multiple planting assemblies in one of the ranks of the machine;

(12) FIG. 11 is a perspective view showing a plurality of frames of the machine;

(13) FIG. 12 is a plan view of a plurality of frames; and

(14) FIG. 13 is a diagrammatic side view of a vehicle towing the machine.

DETAILED DESCRIPTION OF THE DRAWINGS

(15) Referring to FIG. 2, a planting assembly 10 is shown connected to a mounting face 11 of a frame of a planting machine (shown in later Figures) by a cylinder 12. The assembly 10 includes an arm 13 mounted at a pivot point 14 to a connecting section 15 of a parallelogram coupling 16. The coupling 16 has a mounting face 17, also for connection to the frame of the planting machine (not shown).

(16) A cutting tool 18 in the form of a disc 19 is fixed to the connecting section 15 by a connecting arm 15a (see FIG. 6). The arm 13 carries a gauge 20 in the form of gauge wheel 21. The arm 13 also supports a closing wheel 22 at a remote end 23 of the arm 13. The closing wheel 22 is carried by a secondary arm 24 that has an adjustment mechanism 25 and biasing device 26 in the form of a spring 27. The biasing device 26 can instead be in the form of a hydraulic cylinder (as shown in FIG. 5) or an equivalent.

(17) A linkage 28 is pivotally mounted to the coupling 16 and is connected between the arm 13 and an actuator 29 that is pivotally connected to a main pivot 30 of the coupling 16 to rotate as shown by arrows 31. The linkage 28 includes a first member 32 that extends between the actuator 29 and a second junction member 33 that is pivotally mounted at a top pivot point 34, to rotate as shown by arrows 35. The junction member 33 is in turn connected to a third member 36 that is pivotally mounted to the arm 13.

(18) The linkage 28 forms a second parallelogram or pantograph 37 on top of the coupling 16 so as to move in unison with the coupling 16.

(19) Referring now to FIG. 3, the assembly 10 is shown travelling over a ground surface 38 in a direction indicated by arrow 39. The gauge wheel 21 travels on top of the ground surface 38 and the disc 19 is set to cut a trench to a particular depth for planting seed or fertilizer. In the example shown, the planting depth (PD) is 30 mm.

(20) The gauge wheel 21 is designed to follow the ground surface 38 so that the planting depth PD remains substantially constant as the assembly 10 travels over surface contours 40. The cylinder 12 acts to hold the assembly 10 down against the ground surface 38 during a seeding operation. The biasing device 26 serves to force the closing wheel 22 against the ground surface 38 to ensure the trench formed by the cutting disc 19 is closed and packed after seeding.

(21) FIG. 3 shows the assembly 10 in a downward position from that shown in FIG. 2, relative to the mounting face 17. The downward position of the disc 19 and gauge wheel 21 is accommodated by the coupling 16 shifting the pivot point 14 downward, while maintaining a set arm angle relative to the connecting section 15 of the coupling 16 of, for example, 20 degrees. As can be seen, the linkage 28 has moved to a downward position in unison with the coupling 16.

(22) Referring now to FIG. 4, the assembly 10 is in an upward position, where the coupling 16 accommodates a higher position of the arm 13 by allowing the pivot point 14 to be raised relative to the mounting face 17, while maintaining the angle of the arm 13 relative to the connecting section 15, to ensure the planting depth remains constant, despite the assembly 10 being elevated from the position shown in FIG. 3.

(23) Referring to FIG. 5, the assembly 10 is in a levelled position. In this example, the biasing device 26 is in the form of a hydraulic cylinder 41 that replaces the functionality of both the spring 27 and the adjustment mechanism 25, for ease of operation.

(24) In FIG. 5, the actuator 29 is also shown connected to a lateral link 42 that allows for remote actuation by a lever 43. The lever 43 can be moved to rotate the actuator 29 about the main pivot 30 so as to change the orientation of the arm 13 relative to the coupling 16, via the linkage 28.

(25) By lifting or lowering the arm 13 using the linkage 28, the relative height of the gauge wheel 21 and disc 19 is changed and this has the effect of adjusting the planting depth. As such, the planting depth of the assembly 10 can be adjusted remotely of the assembly 10, via the actuator 29.

(26) Referring now to FIG. 6, a reverse or lee side 44 of the assembly 10 is shown where a scraper blade 45, for deflecting dirt and debris away from the disc 19, is illustrated. FIG. 6 also shows a boot 46 through which seed or fertilizer is fed into a trench as the assembly 10 is moved to the right, as shown.

(27) Referring now to FIG. 7, a plurality of planting assemblies 10 is shown, with the planting assemblies 10 arranged in a series of ranks 47, 48, 49, with the associated actuator 29 of each assembly 10 being pivotally connected by fore and aft extending links 50, via the respective lever 43. The links 50 are coupled via a connector 51 to a hydraulic cylinder 52 that drives the links 50, in unison, in the fore and aft direction. As such, the planting depth of all the assemblies 10 can be adjusted simultaneously by the one cylinder 52.

(28) Referring to FIG. 8, a first frame structure 53 is shown, where the links 50 are arranged in a tandem configuration, connected to the respective actuators 29 by the lateral links 42.

(29) With reference to FIG. 9, the assemblies 10 have been removed from the first frame structure 53 for clarity, while another set of assemblies 10 is shown fitted in a second frame structure 54 arranged adjacent the first frame structure 53. The second frame structure 54 also includes a cylinder 52 to drive the associated fore and aft links 50 in a fore and aft direction. The cylinders 52 are phased so that the links 50 in each frame structure 53, 54 can be driven in unison.

(30) With reference to FIG. 10, the rank 47 is shown as including multiple planting assemblies 10, connected to the lateral link 42 so that the linkage 28 of each assembly 10 can be actuated simultaneously and in unison. Multiple planting assemblies 10 are preferably provided in each of the ranks 47, 48, 49.

(31) With reference to FIG. 11, the first frame structure 53 is shown integrated into a centre frame 55 of a planting machine 56. The second frame structure 54 is integrated into a wing frame 57 of the machine 56.

(32) In FIG. 12, another wing frame 59 is shown on an opposite side of the centre frame 55. Each frame 55, 57 and 59 is fitted with an array 60 of planting assemblies 10 across a width and length of the machine 56. The frames 55, 57, 59 are supported on transport wheels 61 although the wheels 61 may be omitted and the frames 55, 57, 59 may instead be self-supporting and not require transport wheels 61 and/or additional wheels 58 may be provided at a front of the machine 56. In either case, a draw bar 62 is provided to connect the machine 56 to a towing vehicle 63, as shown in FIG. 13, which also illustrates a seed bin 64 on top of the draw bar 62.

(33) As may be appreciated, the phased cylinders 52 can be used to control the planting depth of each of the assemblies 10 remotely and the cylinders 52 themselves can all be operated remotely from a cabin 65 of the vehicle 63 to allow for rapid and uniform adjustment of all of the gauge wheels 21 simultaneously, thus providing a significant time and labour saving, as compared to using the prior art adjustment mechanism that requires each assembly to be adjusted manually and independently.

(34) The invention has been described by way of non-limiting example only and many modifications and variations can be made without departing from the spirit and scope of the invention. For example, instead of a disc 19, the cutting tool 18 may instead be replaced by one or a combination of a tine, a point and a point sweep, as required.

LIST OF PARTS

(35) 1. Seeding assembly 2. Cutting disc 3. Gauge wheel 4. Closing wheel 5. Parallelogram coupling 6. Frame 7. Mechanism 8. 9. 10. Planting assembly 11. Mounting face 12. Cylinder 13. Arm 14. Pivot point 15. Connecting section 15a Connecting arm 16. Parallelogram coupling 17. Mounting face 18. Cutting tool 19. Disc 20. Gauge 21. Gauge wheel 22. Closing wheel 23. End 24. Secondary arm 25. Adjustment mechanism 26. Biasing device 27. Spring 28. Linkage 29. Actuator 30. Main pivot 31. Arrows 32. First member 33. Second member 34. Top pivot point 35. Arrows 36. Third member 37. Second parallelogram/pantograph 38. Ground surface 39. Arrow 40. Surface contours 41. Cylinder 42. Lateral link 43. Lever 44. Side 45. Scraper 46. Boot 47. Rank 48. Rank 49. Rank 50. Links 51. Connector 52. Cylinder 53. First frame structure 54. Second frame structure 55. Centre frame 56. Planting machine 57. Wing frame 58. Wheels 59. Wing frame 60. Array 61. Wheels 62. Draw bar 63. Towing vehicle 64. Seed bin 65. Cabin