HYDRAULICALLY POWERED BALER

Abstract

A machine for making bales from plant matter includes a compression chamber, a conveying device for conveying the plant matter into the compression chamber, a piston able to move in the compression chamber in order to compress the plant matter, and a drive device for driving the translational movement of the piston. The drive device further includes a hydraulic device comprising a hydraulic pump connected to the coupling member, a hydraulic motor powered by the hydraulic pump, a drive member driven by the hydraulic motor and configured to move the piston in a translational movement, and a control device for controlling the movement of the piston.

Claims

1-11. (canceled)

12. A machine for making bales from plant matter, said machine being movable with respect to the ground and including: a compression chamber; a conveying device for conveying the plant matter into the compression chamber; a piston able to move in a translational movement within the compression chamber in order to compress the plant matter; a drive device having a coupling member arranged to be connected to a rotating drive element, the drive device being further arranged to actuate the piston in a translational movement; wherein the drive device further includes: a hydraulic device comprising a hydraulic pump connected to the coupling member; a hydraulic motor powered by the hydraulic pump; a drive member driven by the hydraulic motor and configured to move the piston in a translational movement; and a control device connected to the hydraulic device for controlling the movement of the piston.

13. The machine of claim 12, further comprising at least a sensor for determining a filling rate of the compression chamber, said sensor being connected to the control device, and wherein the control device is configured to actuate the movement of the piston when the filling rate is higher than a predetermined threshold.

14. The machine of claim 12, wherein the drive member includes a rod/crank device.

15. The machine of claim 12, wherein the hydraulic pump is a variable flow-rate type pump.

16. The machine of claim 12, wherein the hydraulic motor is a variable flow-rate type motor.

17. The machine of claim 12, wherein the hydraulic motor is reversible.

18. The machine of claim 12, wherein the hydraulic device further includes at least a hydraulic accumulator connected to the hydraulic pump.

19. The machine of claim 18, wherein the hydraulic accumulator is further connected to the hydraulic motor.

20. The machine of claim 12, further comprising a measuring device for determining a force applied by the piston to the plant matter.

21. The machine of claim 12, wherein when the machine is towed by a tractor, the rotating drive element comprises a power take-off of the tractor.

22. The machine of claim 12, wherein the machine is self-propelled.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0046] The invention will be better understood at the reading of the following description of a mode of implementation of the invention given as a nonrestrictive example, with reference to the annexed drawings, on which:

[0047] FIG. 1 is a diagrammatic view of the machine according to the invention, towed by a tractor, the plant matter being conveyed into the compression chamber in order to form a new bale;

[0048] FIGS. 2 and 3 illustrate the machine of FIG. 1 during a pressing phase, by movement of the piston in the compression chamber, in order to form a first portion of the new bale;

[0049] FIG. 4 illustrates the return of the piston, and the filling of the compression chamber;

[0050] FIG. 5 illustrates a subsequent pressing phase during which the second portion of the new bale is formed;

[0051] FIG. 6 illustrates the return of the piston, the new bale being formed while the preceding bale is on the ground; and

[0052] FIG. 7 is a diagrammatic view of the hydraulic circuit of the machine according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

[0053] Illustrated on FIGS. 1 to 6, is an example of a machine 10 according to the invention for making bales B, known as “rectangular” from plant matter V, such as straw, for example. This machine can be moved with respect to the ground S. In this example, the machine 10 is towed by a tractor 12, otherwise known, which includes, at a rear part, a rotating drive element 14, generally called “power take-off”.

[0054] To allow its displacement, the machine 10 includes wheels 11.

[0055] In this example, the plant matter consist in stems, beforehand cut and gathered on the ground as longitudinal piles.

[0056] The machine 10 comprises, in a known way, a compression chamber 16 within which the straw is pressed to form a rectangular bale, and a conveying device 18 for conveying the plant matter into the compression chamber 16. In a known way, the conveying device 18 is associated to a collecting device 20 intended to collect the straw and to direct it towards the conveying device 18. The collecting device 20 will consist in a drum driven in rotation in the opposite direction of the conveying direction of the machine 10. The conveying devices are otherwise known. For example, a comb making a back and forth movement will be used to push the straw into the compression chamber 16.

[0057] To compress the straw and form the bales, the machine 10 includes a piston 22 which is able to move in a translational movement according to a direction D within the compression chamber. The machine 10 further includes a drive device 30 which is arranged to drive the piston 22 in a translational movement. This drive device includes a coupling member 32 arranged to be connected to the rotating drive element 14, i.e. the power take-off 15 of tractor 12.

[0058] In a known way, the machine 10 includes at least one tension plate 34 provided in an upper part of the compression chamber 16, this tension plate having for function to exert a pressure on the bale during formation. Side tension plates can also be provided (non-illustrated herein).

[0059] In accordance to the invention the drive device 30 further includes a hydraulic device 40, as illustrated on FIG. 7. This hydraulic device 40 comprises a hydraulic pump 42 connected to the coupling member 32. As exposed above, the coupling member 32 is connected to the power take-off 15 of the tractor. We thus understand that the rotation driving of the power take-off 15 of the tractor causes the shaft 43 of the hydraulic pump 42 to rotate, via the coupling member 32. In this example, the hydraulic pump 42 is of the type with a variable displacement.

[0060] The hydraulic device 40 further comprises a hydraulic motor 44 which is powered by the hydraulic pump 42. In this example, the hydraulic motor 44 is reversible. It can thus operate as a pump. Moreover, the motor is of the variable displacement type.

[0061] As is viewed on FIG. 7, in this example, the hydraulic device 40 further includes at least a hydraulic accumulator 46 that is connected to the hydraulic pump 42, on the one hand, and to the hydraulic motor 44, on the other hand.

[0062] Coming back to FIG. 7, we can see that the drive device 30 further includes a drive member 60 which is driven by the hydraulic motor 44 and which is configured to move the piston 22 in a translational movement in the direction D. In this example, the drive member 60 includes a device 62 of the rod/crank type, which includes a rod 64 swivellingly connected to the piston 22. The device 62 further includes an eccentric 66, acting as a crank, which is connected to rod 64, on the one hand, and to the hydraulic motor 44, on the other hand. In this example, a reduction box 45 is provided between the hydraulic motor 44 and the eccentric 66.

[0063] In accordance to the invention, the drive device 30 further includes a control device 70 which is connected to the hydraulic device for controlling the movement of the piston. In this example, the control device 70 is configured to control the hydraulic pump 42 and the hydraulic motor 44.

[0064] In this embodiment, the machine 10 further includes at least a sensor 72, provided into the compression chamber, in order to determine the filling rate of the compression chamber 16. This sensor 72 is connected to the control device. In this example, the sensor 72 includes one or more plates actuated by the plant matter when the compression chamber is filled with straw. The pressure exerted by the straw on the plates is such that it triggers a signal representative of the filling rate of the compression chamber.

[0065] In an advantageous way, the control device 70 is configured to actuate the movement of the piston 22 when the filling rate measured by the sensor 72 is higher than a predetermined threshold.

[0066] In addition, the machine further includes a measuring device 74 intended to determine the force applied by the piston 22 to the plant matter. To do this, in this example, the measuring device 74 uses the torque exerted by the eccentric 66 as well as its angular position about its rotating axis X. These values are determined by suitable sensors (non-illustrated herein).

[0067] Using FIGS. 1 to 6, now the operation of the machine 10 according to the invention will be explained.

[0068] When starting the tractor, the compression chamber 16 being empty, the rotation driving of the power take-off 15 causes the hydraulic pump 42 to rotate. At this time, the machine does not carry out any movement, the piston remains motionless and the conveying device is also motionless since not any forward speed is detected. Consequently, there is no or very little energy consumption to operate the machine at this time. In this example, the formation of a new bale B is illustrated in FIG. 1, being specified that a first bale A was previously formed.

[0069] When starting the tractor, the torque at the power take-off 15 increases until the accumulator 46 is completely loaded with the pump 42. After driving the machine 10 in motion with respect to the ground, the collecting device 20 and the conveying device 18 are operated and convey the straw into the compression chamber 16.

[0070] When sensor 72 has determined that the compression chamber 16 is sufficiently filled, the control device actuates the movement of the piston 22, as illustrated on FIGS. 2 and 3. The piston then compresses the plant matter in order to form a first portion B1 of the bale B. It is understood that the first portion B1 is compressed between first bale A and the piston. Concurrently, the tension plate 34 exerts a pressure on the top of the first portion B1 of the bale during formation. In other words, as long as the compression chamber 16 is not sufficiently filled, the piston 22 does not move, contrarily to prior art where the piston is constantly actuated with a back and forth movement.

[0071] As illustrated on FIG. 4, after the first pressing and the formation of the first portion B1, the piston moves back in order to release the compression chamber 16.

[0072] Once that the latter is again sufficiently filled thanks to the conveying means, the piston is actuated in order to compress the plant matter between the first portion B1 and the piston, which creates a second portion B2 of the bale B, such as illustrated on FIG. 5.

[0073] It is understood that the first and second portions B1 and B2 are juxtaposed and form the bale B. In this illustrative example, the bale B is completed at the end of two pressing cycles. Moreover, the first and second portions B1 and B2 are tied together by adapted means, otherwise known.

[0074] In the practice, about twenty back and forth cycles of the piston can be envisaged in order to form a standard bale of 2.4 meters length, 1.2 meters height and 0.9 meter width.

[0075] As illustrated on FIG. 5, during the formation of the second bale B, the first bale A is progressively pushed towards the downstream exit of the machine, up to the moment where it falls on the ground.

[0076] FIG. 6 illustrates the return of the piston after formation of the bale B.

[0077] The bale B is progressively tied during the progression of its formation thanks to tying devices, otherwise known and non-illustrated herein.

[0078] According to an advantageous aspect, during the return of the piston 22 towards the eccentric, the motor 44 operates as a hydraulic pump and generates hydraulic energy which is stored into the accumulator 46. This energy could be used for a later pressing phase.