Machine for harvesting roots such as beets, having a means for automatic adjustment of the harvesting unit

Abstract

Machine for harvesting roots planted in the ground and aligned in rows, comprising a unit (36) for horizontally cutting the head of the roots, said unit having a means for automatically adjusting the level of its cutting blade depending on the level of this head, and being followed by a harvesting unit (48) that hollows out the earth beneath the roots at a relative height beneath the cutting level, characterized in that it has a means for detecting the height of the top of the root e, and a means for adjusting the relative height of the harvesting unit (48) with respect to the cutting level, depending on this height.

Claims

1. A machine for harvesting roots planted in the ground and aligned along rows, comprising a horizontal cutting unit of a head of roots provided with a means for automatically adjusting a level of a cutting blade depending on the level of the head, a harvesting unit configured to dig the ground beneath the roots at a relative height below the cutting level, including a means for detecting a height of a top of the root, and a means for adjusting the relative height of the harvesting unit relative to the cutting level, depending on this height.

2. The harvesting machine according to claim 1, wherein the detection means detects, besides the height of the top of the root, a passage duration of a cutting guide over the top, the adjustment means allowing adjusting the relative height of the harvesting unit relative to the cutting level depending on the height and on the passage duration over the top.

3. The harvesting machine according to claim 2, wherein the means for detecting the passage duration over the top of the root includes a means which detects a force or deformation of a support of the cutting blade of the cutting unit, which is flexible.

4. The harvesting machine according to claim 1, wherein the blade of the cutting unit is mounted on a parallelogram, creating, during the passage of the cutting guide over the root, a movement of the parallelogram which is measured by an angle sensor.

5. The harvesting machine according to claim 1, wherein the means for adjusting the relative height of the harvesting unit includes a hydraulic cylinder driven by an electronic control unit.

6. The harvesting machine according to claim 1, further comprising a device allowing the driver to predefine, for each row, an average level of the harvesting unit prior to its automatic adjustment by the adjustment means.

7. The harvesting machine according to claim 6, wherein each harvesting unit includes a height sensor.

8. An operation method of a machine for harvesting roots planted in the ground and aligned along longitudinal rows, comprising a horizontal cutting unit of a head of the roots provided with a means for automatically adjusting a level of a cutting blade depending on a level of the head, which is followed by a harvesting unit digging the ground beneath the roots at a relative height below the cutting level, performing a detection of the height of the top of the root, and adjusting the relative height of the harvesting unit relative to the cutting level, depending on this height.

9. The operation method according to claim 8, further comprising detecting the passage duration over the root by the cutting unit, the relative height of the harvesting unit relative to the cutting level being adjusted depending on this passage duration over the root.

10. The operation method according to claim 8, further comprising a preliminary step for predefining the average level of the harvesting unit.

11. The operation method according to claim 9, further comprising, starting from the average relative height, for a significant passage duration of the cutting unit over the root, increasing the relative height, and for an average duration, keeping the relative height, and for a shorter duration, reducing then relative height.

12. The operation method according to claim 8, further comprising, in the absence of any detected root, setting the relative height to the minimum.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention will be better understood and other features and advantages will appear more clearly upon reading the description hereinafter given as example, with reference to the appended drawings in which:

(2) FIG. 1 is a longitudinal sectional view of a beet planted in the soil, ready to be harvested;

(3) FIGS. 2a, 2b and 2c are cross-sectional views of six rows of beets corresponding to the cutting width of a harvesting machine;

(4) FIG. 3 is a side view of a harvesting machine according to one embodiment of the invention;

(5) FIG. 4 is a cross-sectional view of the harvesting units of this machine;

(6) FIG. 5 presents the operation of this machine on a longitudinal sectional view of a row of beets;

(7) FIG. 6 presents on the same sectional view, the gain in the digging depth enabled by the harvesting machine; and

(8) FIG. 7 presents a longitudinal sectional view of a row of beets according to another embodiment.

DETAILED DESCRIPTION

(9) It is to be noted that the following schemes and explanations are based on a harvesting machine with six rows. The invention applies in the same manner to harvesting machines adapted to a smaller or larger number of rows. In particular, the larger is the number of uprooted rows, and the greater will be the benefits related to the invention. Indeed, the irregularities of the terrain and of the beets will be higher over eight, nine or twelve rows than over six rows. Hence, an optimization of the depth of the harvesting level of each row will result in an increased benefit.

(10) FIG. 1 presents a beet 2 buried in the soil including a surface level 6, which has to be harvested as it matures.

(11) To be harvested, the top of each beet 2 has to be first cut horizontally along the cutting level 12 located slightly beneath its top 4, in order to eliminate the leaves growing on this beet. The cutting of the top of the beet 4 then leaves a cutting plane with a width L, which depends on the size of this beet.

(12) The harvesting machine according to the prior art, including a means for automatically adjusting the cutting level, is provided with a guide at the front of the cutting blade which follows the upper contour of the beets 2 when advancing, in order to achieve the placement of the blade at the proper cutting level 12.

(13) The harvesting level located in the soil 8 represents the ideal level for digging the soil in order to harvest the beet 2, just beneath its main volume. Digging too deep uselessly consumes more energy to power the harvesting machine, and results in too much soil with the beets 2, while digging not deep enough risks damaging these beets.

(14) Then, we obtain for each beet a relative height H comprised between the cutting plane 12 and the harvesting level 8, which may vary within the same row depending on numerous parameters, comprising in particular the local quality of the soil, the moisture content, the longitudinal space between two beets, the burial depth of this beet, and the yield proper to each of the beets.

(15) FIGS. 2a, 2b and 2c present different possible deformations of the harvesting field which extend longitudinally over this entire field, over six rows of beets which are harvested at the same time.

(16) The line 22 represents the general inclination of the harvesting machine, the upper curve 6 represents the level of the surface of the soil, and the lower curve 8 represents the desired harvesting level set individually for each row, corresponding to the base of the lateral blades 60 of the harvesting unit brought to dig the ground just beneath each beet.

(17) FIG. 2a presents a cross-section of the surface of the soil 6 which is convex, the harvesting level 8 of the rows two to five has to be raised.

(18) FIG. 2b presents a cross-section of the surface of the soil 6 which falls down on the right side, for example at the boundary of a field, the harvesting machine being inclined. The harvesting level 8 of the rows two to four has to be raised, the harvesting level of row six has to be lowered.

(19) FIG. 2c presents a cross-section of the surface of the soil 6 comprising a space 20 between the rows two and three which has been compacted by the passage of a machinery, thereby forming a rail. The harvesting level 8 of rows two and three has to be lowered.

(20) FIG. 3 presents a harvesting machine including at the front two independent guide wheels 30 intended to follow the rows of beets, which are connected to the entire machine by articulated arms 32 each provided with a position sensor 34 sending a signal to the electronic control unit 54.

(21) The guide wheels 30 allow determining the line 22 representing the general inclination of the harvesting machine, the individual harvesting levels of each row 8 being determined with respect to this line.

(22) Afterwards, there is a leaf-stripping unit 35 which removes most of the leaves of the beets.

(23) Afterwards, there are six independent units for cutting the head of the beets 36 transversely aligned, each comprising upstream of the horizontal cutting blade a guide means curved at the front which is brought to slide over the top of each beet, in order to adjust the height of this blade located just behind.

(24) The predefined height of the cutting unit 36 is measured by the sensor 38.

(25) Each cutting unit 36 comprises a guide and a cutting blade mounted on a deformable parallelogram fitted with an angle sensor 40, which allows measuring the relative height of the guide as it passes over the beet 2, and therefore the height of the top 4 of this beet. This angle sensor 40 also allows measuring the duration during which the guide and the cutting blade are raised, which allows deducing the size of the beet 2.

(26) The information on the height of the cutting unit 36 and on the deformation of the parallelogram 40 is sent to the electronic control unit 54. Thus, a succession of signals over time is obtained giving, if the forward speed of the harvesting machine is known, the indication of the width of each beet by measuring, thanks to the angle sensor 40, the duration of the parallelogram rise, and the indication of the height of the top of the beet 4 from the inclination of this parallelogram.

(27) Behind each unit for cutting beets 36, there is a harvesting unit 48 comprising a wheel presenting at each side the succession of blades 60 which are brought to dig the ground just beneath each beet in order to uproot them, and send them to the rear where they are undertaken by a lifting system 58.

(28) Each of the six harvesting units 48 has a predefined average level relative to the harvesting machine, set by a cylinder 44 based on the position of the leaf-stripper 35.

(29) For each row of beets, the driver can predefine the average level of each harvesting unit 48, based on the general condition of the surface of the soil 6 of this row, as presented in FIGS. 2a, 2b and 2c. Each harvesting unit 48 is provided with more than one independent hydraulic cylinder 50 for modifying its height relative to its predefined average height, which adds or subtracts a small value so as to give an adjustable relative height H, which is driven by hydraulic valves 56 controlled by the electronic control unit 54.

(30) Based on all the received information, in particular those given by the angle sensor 40 indicating the duration and the height, the electronic control unit 54 reacts very rapidly so as to accurately adjust the relative height H, in order to obtain the proper harvesting level 8 adapted to each beet 2 which has just been cut.

(31) Alternatively, the beet cutting detection may include a different measuring means, such as a pressure or force sensor, a physical probe, a multi-dimensional scanner or a three-dimensional camera.

(32) FIG. 5 presents the curve of the cutting level 10 given by the angle sensor 40, and the signal 80 sent by this sensor, comprising rectangles indicating the absence of rise of the parallelogram holding the cutting blade, and spaces L between these rectangles indicating the times of passage over the beets by the guide of the cutting blade.

(33) The adopted strategy is the following, illustrated by sets of beets comprising successively, starting from the left side of the drawing, a first set 70, a second set 72, a third set 74, a fourth set 76 and a space 78 left empty.

(34) As regards the set 70, the beets 2 are big and their top is at the average level of the soil. These characteristics are detected by the angle sensor 40 of the parallelogram of the cutting blade, and by a significant time of passage over the beet. The relative height H is increased so as to ensure not to damage the base of this beet.

(35) As regards the set 72, the beets are big and have grown out of the ground. These characteristics are detected by the angle sensor 40 of the parallelogram of the cutting blade, and by a time of passage over the beet. The relative height H is also significant, but since the height of the top of the beets is high, the harvesting unit will be raised relative to its average position.

(36) In the case of the set 76, we have small beets, which have grown relatively above the level of the soil. Hence, the harvesting unit will be raised in order to take into account a small relative height H and a top of the beet which is high. If no beet is detected, which corresponds to an absence of detection by the angle sensor 40, the relative height H is set to the minimum. This characteristic is presented by the empty space 78.

(37) FIG. 6 presents a black surface corresponding to the difference of height between a constant harvesting level 90 used by harvesting machines of the prior art, and the harvesting level 8 optimized by the method according to this embodiment. We notice an absence of damaging of the beets 2, and at the same time, and adjustment of this harvesting level 8 to the highest, reflected in an energy saving for the pulling force of the machine, and in a lesser amount of soil uselessly carried.

(38) Alternatively, the adjustment of the relative height H of the harvesting unit 48 relative to the cutting level 10 may be based only on the height of the top 4 of the root 2 detected by the detection means.

(39) In such a configuration, each cutting unit 36 comprises a guide and a cutting blade mounted on a deformable parallelogram fitted with an angle sensor 40, which allows measuring the relative height of the guide as it passes over the beet 2, and therefore the height of the top 4 of this beet. Afterwards, the information is sent to the electronic control unit 54 which adjusts the relative height H based on the height of the top 4 of this beet in order to obtain a harvesting level 8 adapted to each beet 2 which has just been cut.

(40) Thus, the strategy adopted in this case is substantially similar to the previously described one with the difference that the electronic control unit 54 proceeds to the adjustment of the relative height H based only on the height of the top 4, as if the size of the root was considered to be constant.

(41) Preferably, in this case, the angle sensor 40 allows measuring the maximum heights corresponding to the heights of the tops 4 of the roots and the minimum heights corresponding to the heights without any roots, the electronic control unit 54 comprising a filter allowing smoothing a displacement of the harvesting unit 48 based on a filtered average height of the tops 4 of the beets.

(42) FIG. 7 presents a curve of the cutting level 10 given by the angle sensor 40, the curve of the harvesting level 8 optimized with the method according to this embodiment corresponding to the smoothing of the curve 10. In other terms, the operation method of this harvesting machine includes a step of smoothing the displacement of the harvesting unit 48 based on a filtered average height of the top 4 of the beets.

(43) Yet, such a configuration is substantially less accurate than that in which the detection means detects, besides the height of the top of the root, the passage duration of the cutting guide over this top, the adjustment means allowing adjusting the relative height of the harvesting unit relative to the cutting level based on this height and on this passage duration over the top. Nonetheless, one of the advantages of this configuration is that it requires a lower energy consumption, and therefore a lesser fuel consumption.