RU2790686C2 - Unit for addition of agricultural substance into the soil and agricultural machine containing such unit - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: unit adding agricultural substance into the soil for an agricultural machine and an agricultural machine containing such a unit, configured as an installation fixed to the agricultural machine. The unit for adding into the soil comprises a control device and a device for adding into the soil. The control device is configured to rest on the ground in the working configuration and serve as a depth positioning control element for the device for adding into the soil. The device for adding into the soil is configured to add an agricultural substance to the soil in an operating configuration. The control device is configured with the possibility of articulated installation directly on the support, which is fixed relative to the agricultural machine. The control device is configured to exert weight on the device for adding into the soil in the working configuration by means of a stop located between the control device post and the post of the device for adding into the soil. The control device creates the first means of applying a pressing force to the device for adding into the soil.

EFFECT: reduced labour intensity of adjustment of the device for adding agricultural substances into the soil.

28 cl, 7 dwg

Description

The invention relates to the general technical field of agricultural mechanization and, in particular, to the field of sowing and fertilization.

The invention relates to an element for introducing into the soil a liquid or solid substance for agricultural purposes. Such an agricultural substance may be a liquid or granular fertilizer, a liquid or granular insecticide, or may be seeds.

The element for applying fertilizer to the soil is installed, for example, in front of the support beam of the dotted sowing element, either directly opposite or offset relative to the dotted sowing element and the exit of the seeds from the dotted sowing element, depending on whether it is required to apply fertilizer in the furrow into which the seeds are embedded , or side by side along a line parallel to this furrow.

In FIG. 2 of patent application EP 2622954 B1 shows a dotted planter in which such a unit 5 for applying fertilizer to the soil is located with a slight offset relative to the dotted sowing element 4.

Another prior art seeding plant 810 is shown schematically in FIG. 1. The soil application unit 810 includes a control device 840 and a soil application device 850. The control device 840 is mounted on a bracket 812 by means of a first pivot pin 843. This bracket 812 is in turn mounted on a frame 811 which can be considered as a fixed support for the seed spreader 810. The control device 840 includes a furrow wheel 841 configured to rest on the ground 5 and serve as a depth control element for the soil application device 850. The soil spreader 840 includes a disc furrow maker 851 and a column 852. A disk furrower 851 is mounted on the column 852. The column 852 is mounted by means of a second rotary axis 853 on the column 842 of the control device 840. The disk furrower 851 is configured to open a furrow 6 into which seeds are sown. The post 852 has an adjustable stop 854, while the post 842 includes a fixed stop 844. A spring 813 is installed between the bracket 812 and the post 852. The spring 813 tends to push the disc furrower 851 into the ground. The furrow wheel 841 limits the depth of the disc furrower 851 when the adjustable stop 854 comes into contact with the fixed stop 844. In other words, the control device 840 supports the soil spreader 850.

In this seed spreader 810, the depth force of the spreader 850 is provided by a spring 813. The control device 840 is configured to limit the depth of the disc furrower 851. This design forces a massive spring 813 to be provided to ensure that the adjustable stop 854 contacts the fixed stop. 844 and therefore that the disc furrower 851 reaches the required depth.

In the shown in FIG. 1 seeding unit 810 with the same elastic element parameters, changing the depth setting using a set of stops 844 and 854 leads to an angular movement of the column 852 relative to the control device 840. In this case, the spring 813 rotates around its attachment point on the bracket 812, and its length, i.e. its compression ratio, changes. These changes in the orientation and compression of the spring 813, in a non-zero total, change the effect of the ground penetration force applied by the spring 813 on the soil applicator 850. Thus, the penetration force changes in an undesirable manner when the depth adjustment is changed.

In FIG. 2 schematically shows a known fertilizer application unit 910. This soil application assembly 910 includes a control device 940 and a soil application device 950. The soil applicator 950 is mounted on a bracket 912 by means of a first pivot pin 953. This bracket 912 is in turn mounted on a frame 911, which can be considered a fixed support for the fertilizer applicator 910. The soil applicator 950 includes a disc furrower 951 mounted at the end of the tine 952 and configured to open a furrow 6 into which the granular fertilizer will be applied. A spring 913 is installed between the bracket 912 and the post 952 to ensure that the disc furrower 951 is driven into the ground 5. The hub 956 of the disc furrower 951 is through. The through hub 956 encloses and supports the pivot axle 943 of the monitor 940. The monitor 940 also includes a furrow wheel 941 and a strut 942. The first end of the strut 942 is mounted on the axle 943. rest on the ground and serve as a depth control element for the disc furrower 951. In this unit 910 of applying fertilizer to the soil, the rack 942 and the wheel 941 are located on the side of the disc furrower 951, opposite the rack 952. An adjustment grid 954 with holes 955 is fixed on the rack 952. Adjusting knob 944, which includes a control device 940, can be adjusted in angular position 957 relative to the post 952 and locked in one of the holes 955. A locking device 958 is provided to hold the adjustment knob 944 in position relative to the adjustment grille 954 (FIG. 2). Since the adjustment knob 944 and the post 942 are fixed relative to each other, adjusting the knob 944 relative to the post 952 of the soil applicator 950 changes the relative position of the furrow wheel 941 relative to the bracket 912 and therefore changes the depth of penetration of the disc furrower 951.

In the system shown in FIG. 2, while setting the depth of the disc furrower 951, changing the angular position 957 causes the tine 942 to move significantly relative to the tine 952. Therefore, the depth adjustment affects both the orientation and the length, i.e. the compression ratio of the spring 913. described with reference to FIG. 1, changes in the orientation and compression of the spring 913, in a non-zero sum total, change the effect of the ground penetration force applied from the spring 913 on the soil applicator 950. Thus, the penetration force changes in an undesirable manner when the depth adjustment is changed.

In the system shown in FIG. 2, the angle adjustment 957 forces the furrow wheel 941 to be raised manually, which is a laborious operation, especially since this adjustment is usually necessary on all soil spreaders included in the agricultural machine (sometimes 16, 24 or 36 rows and even more ).

The invention aims to provide a simple alternative and improved solution to existing soil application systems for an agricultural substance that requires as little adjustment as possible.

Thus, the object of the invention is a unit for applying an agricultural substance to the soil for an agricultural machine, made with the possibility of a fixed installation relative to the agricultural machine, while the unit for applying to the soil contains a control device, a device for applying to the soil, while the control device is made with the ability to rely on ground in the working configuration and serve as a depth positioning control element for the soil application device, while the soil application device is configured to apply an agricultural substance to the soil in the working configuration, while the control device is made with the possibility of articulated installation directly on a fixed support relative to agricultural machine. In the aforementioned soil applicator, the control device is configured to exert weight on the soil applicator in the operating configuration, the control device forming a means for applying a pressing force to the soil applicator.

Due to the effect of the weight of the control device on the soil applicator, the control device in this case acts on the soil applicator in the direction of the ground in the working configuration, and not opposite to the ground, as in the device 810 described with reference to Figs. 1. In other words, in the device 810, the weight of the control device is not used, while in the present invention it is used to help deepen the application device into the soil. Therefore, the soil applicator uses the load from the weight of the control device for its penetration. This makes it possible to limit the dimensions of the possible second means of applying force to the soil applicator, and even if the weight of the control device is sufficient to ensure that the device is buried in the soil to the required depth, to do without a second means of applying force, separate from the control device.

Preferably, the soil application unit comprises a second pressing force application means, wherein the second pressing force application means is configured to apply additional pressing force to the control device.

In a particular configuration of the soil application unit, the second pressing force application means assists in applying or itself applies additional pressing force to the control device.

Preferably, the second pressing force application means is configured to apply a pressing force to the control device in an operational configuration, wherein the control device is configured to transmit the pressing force to the soil applicator.

Preferably, the second pressing force application means can be adjusted in several positions with respect to the control device or with respect to a support fixed relative to the agricultural machine, in order to change the pressing force exerted by the second pressing force application means on the control device in the operating configuration.

Preferably, the second pressing force application means comprises a resilient element configured to exert a pressing force on the control device in the operating configuration.

Preferably, the elastic element can be adjusted in position and/or adjusted in tension. Thus, the pressing force application means may comprise a position adjusting device, for example, to adjust the position of the compression spring. Alternatively, or in combination with a position adjustment device, the pressing force application means can also be provided with a length adjustment device and/or a tension adjustment device, for example in the case of a compression spring, to adjust the length of the compression spring.

Preferably, the resilient element comprises a compression spring, an extension spring, a torsion spring, or a torque tube.

Preferably, the second pressing means is a removable weight device(s) comprising at least one removable weight.

Preferably, the control device comprises a furrow wheel and/or the soil spreader comprises a furrow opening element and a means for releasing the agricultural substance.

Preferably, the soil application unit comprises a depth setting device configured to adjust the soil application depth of the soil application device with respect to the control device. With this adjustable stop, and in a position where the control device can exert weight on the soil applicator in working configuration, depth adjustment is exceptionally easy. Indeed, the depth adjustment is carried out in the raised position of the machine. In this raised position, the control device stops pressing the depth setting device. Thus, in this configuration of the invention, there is no need for the user to lift the control device to adjust the depth of application to the soil, unlike the application device shown in FIG. 2 or overcome resistance from a pressing force application means such as the spring 813 of the soil applicator shown in FIG. 1 which presses the soil applicator 850 against the fixed stop 844. Therefore, depth adjustment is made easier for the user.

In addition, in a particular embodiment, in which the soil application unit additionally comprises an elastic element, the pressing force of the elastic element does not depend on the depth of application to the soil. Indeed, the control device rests on the ground (both in the known solution and within the scope of the invention) at what is considered a constant distance from the frame of the agricultural machine, which itself is at a fixed height relative to the ground. In this embodiment, preferably the elastic element is not affected by changes in the depth of application to the soil; in other words, the pressure exerted on the soil applicator by the elastic element is constant at any depth adjustment. Therefore, the adjustment of the soil spreader is more reliable and predictable than known solutions.

Preferably, the depth setting device comprises an adjustable stop, wherein the adjustable stop can occupy at least two different positions, each of these two positions corresponding to the depth of application of the agricultural substance into the soil by the soil application device.

Preferably, the adjustable stop is a helical stop, preferably containing holding means in position, preferably in the form of depressions.

In a variant, the adjustable stop can be adjusted in position by screwing.

The object of the invention is also an agricultural machine containing the above-described unit for introducing an agricultural substance into the soil.

Other features and advantages of the invention will become more apparent from the following description of non-restrictive examples with reference to the accompanying drawings.

In FIG. 1 schematically shows a known fertilizer application unit;

in fig. 2 is a schematic representation of a known seeding plant;

in fig. 3 is a schematic diagram of a plant for applying an agricultural substance to the soil in accordance with the present invention;

in fig. 4 shows an embodiment of the soil application unit shown in FIG. 3, in working configuration, side view;

in fig. 5 shows the soil application unit shown in FIG. 4 is a perspective view from the opposite side;

in fig. 6 shows a soil application depth adjustment stop that may be included with the soil application unit shown in FIG. 4 and 5, detailed view;

in fig. 7 shows in detail the depth setting device rotatably coupled to the depth adjustment stop shown in FIG. 6 is a perspective view.

Fig. 3 schematically illustrates the design principle of the soil application unit 10 for releasing an agricultural substance. With reference to Fig.4-6 presents a description of a particular variant 20 of the execution of the unit 10 in the soil.

The agricultural material released by the application unit 10 into the soil is, for example, solid fertilizer (such as granules), liquid fertilizer or seeds. The plurality of soil application units 10 described below can be applied to the agricultural machine 9 (shown very schematically in FIG. 3) in a quantity corresponding to the number of working rows. The agricultural machine is, for example, a seed drill or a fertilizer spreader.

As shown in FIG. 3, the soil application unit 10 comprises in this case a bracket 12, a control device 40 constituting a first pressing force application means, a second (optional) pressing force application means 13 and a soil application device 50 .

The bracket 12 is non-restrictively fixed to the frame 11 of the agricultural machine. In the present description, the terms "front", "rear", "upper" and "lower" are used in relation to the general forward direction A of the agricultural machine. The forward direction A is indicated by an arrow in FIG. 3-6.

Bracket 12 may be configured to be positioned in a non-restrictive manner in front of beam 110 of frame 11, as in the embodiment shown in FIG. 4-6. Alternatively, and non-restrictively, the bracket 12 may be located under or behind the beam of the frame 11. In the embodiment shown in FIG. 4, beam 110 has a dovetail front section. This shape is not restrictive, and the beam 110 may be square, rectangular, or other shape.

The control device 40 includes a rotary axle 43, a rack 42 and a furrow wheel 41.

Rack 42 is installed with the first end on the bracket 12 using a rotary axle 43. Furrow wheel 41 is mounted on the second end of the rack 42.

During operation, the furrow wheel 41 rests on the ground 5 and rolls on the ground.

In general, the control device 40 forms a depth control element for the soil application device 50 .

The control device 40 is pivotally mounted on the bracket 12 independently of the soil spreader 50 . In other words, the control device 40 is pivotally mounted on the bracket 12 without an intermediate kinematic installation of the soil spreader.

In general, the control device 40 is mounted by means of a mechanical connection on a support that is fixed relative to the agricultural machine, regardless of the soil application device. As mentioned above, the fixed support is the bracket 12, mounted on the frame 11 of the agricultural machine. In a variant not shown in the figures, the fixed support is, for example, the frame 11 of an agricultural machine.

In another embodiment not shown, the mechanical connection between the control device 40 and the fixed support is different from the pivot shaft 43. Thus, the mechanical connection can be, without limitation, a yoke connection or a connection by means of a deformable mechanism such as a parallelogram.

The soil spreader 50 comprises a rotary axle 53, a column 52, a soil spreader 51, which in this case is a disc furrower, and a soil spreader 56 .

Post 52 is mounted with its first end on post 42 by means of a pivot pin 53. Pivot pin 53 is located below pivot pin 43 (FIG. 4). The pivot shaft 53 allows the soil spreader 50 to swing upward during operation when it encounters an obstacle such as a stone. A disc furrower 51 is mounted on the second end of the column 52. The disc furrower 51 is configured to cut the soil. The soil application element 56 follows the disc furrower 51. The soil application element 56 includes a coulter capable of opening a furrow 6 in the soil 5, such as the coulter 560 described with reference to FIGS. 4 and 5. In this case, the soil application element 56 introduces the agricultural substance into this furrow 6.

The second pressing force application means 13 is in this case an elastic element such as a compression spring. The second pressing force application means 13 is designed to exert a pressing force on the control device 40 to press the furrow wheel 41 against the ground 5 and keep it in contact with the ground 5 to ensure that the material is applied to the desired depth.

Between the posts 42 and 52 there is a stop 14. In this case, the stop 14 is made on the stand 52. The stop 14 serves as the point of contact of the stand 42 with the stand 52 at the intermediate point of the stand 52 between the disk furrower 51 and the rotary axis 53. Thanks to this contact, the weight P of the control device 40 acts on the soil applicator 50 and contributes to its penetration into the ground 5. Thus, the control device 40 forms the first means of applying a pressing force to the soil applicator 50, with the weight P being the first pressing force. The structure of the soil application unit 10 shown in FIG. 3 is designed in such a way that the control device 40 exerts its weight on the soil spreader 50 . In addition, the control device 40 transmits to the soil spreader 50 the second pressing force F, which is acted upon by the second pressing force application means 13 . Thus, the total penetration force E acting on the soil spreader 50 is the sum of the pressing force F exerted by the second pressing force application means 13 on the control device 40 and the weight P of the control device 40 (see arrows F, P and E in Fig. 3). Thus, by applying the weight of the control device 40 to the soil spreader 50, the pressing force F applied by the second pressing force application means 13 to cause the soil spreader 50 to penetrate into the ground 5 can be reduced. This makes it possible to lighten and reduce the size of the second pressing means 13 in comparison with the known solutions, and even eliminate it if the weight P is sufficient to achieve the required depth of application to the soil.

In embodiments, the pressing means formed by the abutment 14 may be implemented differently, for example, may be located on the rack 42 or may be implemented through the interaction of elements, such as the protrusion 55 and the depth setting device 70 described below (Fig. 4) .

Further with reference to Fig. 4-6 follows a description of the embodiment 20 of the unit 10 for applying to the soil.

Bracket 30 (FIG. 4) is a particular embodiment of bracket 12 (FIG. 3). Bracket 30 contains a rack 31 and the device 32 fasteners.

In this case, the attachment device 32 includes an upper hook 320, a lower hook 321 and a tightening system 322.

In this case, the upper hook 320 is integral with the post 31, while the lower hook 321 is movable and adjustable, in this case vertically, relative to the post 31. In an embodiment not shown in the figures, the upper hook 320 is movable and adjustable relative to the post 31. The lower hook 321 can also be integral with the column 31 when the upper hook 320 is fixed or integral with the column 31.

In this case, the front side 323 of the column 31 is vertical. The top hook 320, the bottom hook 321 and the front side 323 in this case form a nest with a dovetail section corresponding to the front section of the beam 110. Thus, in the illustrated configuration, the fastening device 32 is designed to engage on the corresponding outer profile of the frame 11 of the agricultural machine , in this case on the outer profile of the beam 110. The tightening system 322 in this case includes a screw for fastening and holding in position on the frame 11.

Post 31 in this case extends forward and downward from beam 110 (FIG. 4).

The bracket 30 also includes an upper attachment device 33 . In this case, the upper attachment device 33 comprises a plurality of holes 331 and a first pin 65. The holes 331 are provided in the column 31, in this case not restrictively near the attachment device 32. Preferably, the holes 331 extend through the post 31, preferably horizontally and transversely to the intended direction of travel A of the machine. The openings 331 are arranged side by side, in this case not restrictively located along a circular arc 3311 when viewed from the side of the soil application unit 10 (FIG. 4). Preferably, but not restrictively, in the present embodiment, when viewed from the side, the center of the circular arc 3311 is located on the axis of rotation 660 of the second pin 66 on which the compression spring 61 described below is mounted. The first pin 65 is shaped to match the holes 331 so that it can be mounted fixedly but removably in one of the holes 331 (for example, along the axis 3310 common to the pin 65 and the corresponding hole 331, as shown in Fig. 5).

In this case, in addition to the elements described with reference to FIG. 3, the control device 40 includes (FIGS. 4-6) a first stop 44 and a second stop 45. In this case, both stops 44 and 45 are made integral with the post 42. The stop 44 forms a lower stop, that is, limits the lowering of the control element 40 during the lifting of the agricultural machine and hence the spreading unit 10 . In this case, the stop 44 comes into contact with a corresponding cross element belonging, for example, to the post 31. The stop 45 forms a contact element for the stop 54 described below.

In this case, in addition to the elements described with reference to FIG. 3, the soil applicator 50 includes (FIGS. 4-6) an abutment 54, a protrusion 55, and a soil applicator 56.

The stop 54 forms a bottom stop (FIGS. 4 and 6), ie it limits the lowering of the soil spreader 50 during lifting of the agricultural machine and hence the soil spreader 10 . In this case, the stop 54 comes into contact with the stop 45 of the control device 40. In this case, the stop 54 is a protrusion made in one piece with the rack 52. In this case, the stop 54 is installed in the immediate vicinity of the rotary axis 53 opposite to the disk furrower 51 along relation to the rotary axis 53.

The protrusion 55 (FIGS. 4 and 6) forms an element of contact with the helical stop 71 described below, while the protrusion 55 and the helical stop 71 are part of the depth setting device 70.

In this case, the soil application element 56 (FIG. 5) includes a flange 57, a coulter 560, and a distribution pipe 59.

The flange 57 is secured with its forward end to the post 52 by means of fixing means 580, in this case screws, not limited to two. The fastening device 58, in this case also a screw, allows the hub 510 of the disc furrower 51 to be fixed to the column 52.

Distribution pipe 59, the lower end of which is shown in FIG. 5 is attached to the rear end of the flange 57. The dispensing pipe 59 is connected to the outlet of a tank (not shown) with an agricultural substance included in the machine. Distribution tube 59 shown is configured to release granular fertilizer into furrow 6. Fertilizer is released through the lower outlet 590 of distribution tube 59 (FIG. 5) at ground level 5, in this case into furrow 6.

The lower end of the distribution tube 59 is fixed to the coulter 560 on its rear side.

The elastic element 60 (Fig. 4) is a particular embodiment of the second means 13 for applying the pressing force (Fig. 3). In this case, the elastic member 60 can be adjusted by the position adjustment device. This adjustment of the position in this case is provided by the upper attachment device 33 described above. The elastic element 60 includes a compression spring 61, a lower trunnion 63, an upper trunnion 64, a first pin 65 and a second pin 66.

The compression spring 61 is mounted on trunnions 63 and 64 between these trunnions. The upper trunnion 64 is mounted on the post 31 in one of the holes 331 by means of the first pin 65 (FIGS. 4 and 5). Pin 65 may be held in place with a cotter pin, such as an automatic cotter pin. The lower trunnion 63 is rotatably mounted on the column 42 by means of a second pin 66 (FIGS. 5 and 6).

In this case, the elastic element 60 also contains the adjustment device 62. The adjustment device is both a tension adjustment device and a length adjustment device. In this case, the adjusting device is the adjusting screw 62. The adjusting screw 62 is installed in the inner bore of the lower trunnion 63. The adjusting screw 62 also extends longitudinally inside the compression spring 61, with respect to which the adjusting screw 62 is coaxial. With its end opposite to the head, the adjusting screw 62 abuts against the upper trunnion 64.

In an adjustment configuration, the pin 65 is removed from the holes 331 and the compression spring 61 can be rotated about the axis 660. Acting on the adjustment screw 62 allows the length of the spring 61 to be adjusted for mounting on the post 31. Through the adjustment screw 62, the not-shown hole of the top trunnion 64 can be positioned opposite one of the holes 331. A pin 65 can then be inserted into said hole 331 and into the hole of the upper trunnion 64 to secure the spring 61 with respect to the post 31 (FIGS. 4 and 5). The choice of hole 331 determines the orientation of the spring 61 with respect to the second pin 66 and the post 42. The angular position of the spring 61 with respect to the post 42 will determine the direction of the pressing force F of the spring 61 on the post 42.

Depth setting device 70 comprises the aforementioned helical stop 71, shaft 73 and setting element 74. Depth setting device 70 allows adjustment of the depth of the furrow 6 in relation to the ground 5, that is, in this case, the working depth of the disc furrower 51 in relation to the furrow wheel 41.

The helical stop 71 is a contact element whose diameter varies from its axis of rotation 730 . The non-restrictively helical abutment 71 comprises two flat sides. Preferably, the helical abutment 71 includes retention means, in this case in the form of dimples 72. The shape of the bottom of the dimples 72 preferably matches the shape of the protrusion 55 for good retention of the helical abutment 71 in the angular position.

The helical stop 71 is mounted on the shaft 73, in this case fixedly. The shaft 73 is generally oriented along an axis 730 parallel to the axes 43 and 53, that is, transverse to the general direction of movement A of the agricultural machine (FIG. 5). The helical stop 71 may be secured to the shaft 73 by welding, screwing, pressing, or other means or method of fastening.

The setting member 74 is configured as a latch 75 and a return device 79. The setting member 74 also forms a holding element in position for the depth setting device 70. The setting element 74 serves to determine and maintain the soil application depth for the soil application device 50 relative to the control device 40.

The latch 75 is a plate equipped with tabs 76, teeth 77 and notches 78.

The paws 76, in this case two in number, form the retaining element of the latch 75. The teeth 77 are made in the form of protrusions on the latch 75.

Recesses 78 are recesses in post 42. Teeth 77 can fit into recesses 78 while latch 75 is raised and hold latch 75 in position on post 42.

Latch 75 and helical stop 71 are fixedly connected in an angular direction relative to each other in such a way that changing the angular position of the latch 75 by the user allows you to adjust the angular position of the helical stop 71. Preferably, the latch 75 is made to slide on the shaft 73, for example, by matching with a section (for example, polygonal) of the shaft 73.

In this case, the return device 79 includes a spring 790, a washer 791 and a screw 792. The springs 790 are located around the shaft 73 and are held on the latch 75 and on the shaft 73 by the screw 792 and the washer 791 (FIG. 7). The return device 79 is designed to press the latch 75 to the plinth 420 belonging to the post 42. Thus, the teeth 77 are held in the recesses 78. This allows you to securely maintain the position occupied by the setting element 74 relative to the post 42.

Depending on the angular position that the spiral stop 71 occupies around its axis of rotation 730 relative to the post 52 (or ledge 55), the distance between the axis 730 and the post 52 changes. This allows you to adjust the gap between the posts 42 and 52, that is, the difference in height between the furrow the wheel 41 and the disc furrower 51, and hence determine the soil application depth for the soil application device 50 .

The position of the tabs 76 makes it possible to note the adjustment being made and to reproduce it on the various units 10, 20 of applying to the soil of the seeder in order to apply the agricultural substance at the same depth from one row to the next.

The adjustment of the spreader 20 is made when the machine is in the raised position, that is, on the one hand, when the stop 44 comes into contact with the column 31, and, on the other hand, when the stop 54 comes into contact with the stop 45. Thus , the elastic member 60 is not compressed between the posts 31 and 42 and can be adjusted by the user without effort. Similarly, the depth setting device 70 does not come into contact with the post 52. In the embodiment described with reference to FIG. 4-6, the depth setting device 70 is adjusted without any tool. Indeed, in this raised position, the helical stop 71 does not come into contact with the post 52. Thus, the user can easily and effortlessly adjust the depth of application to the soil. This makes it easy to parameterize the soil application unit 20 .

The control device 40 is configured to rest on the ground 5 in the working configuration and forms a control element for the depth positioning of the soil spreader 50 . Indeed, during operation, the disk furrower 51 tends to rise under the action of friction forces with the ground 5. The control device 40 presses its weight on the rack 52 of the device 50 into the soil at the level of the stop 13 and prevents the device 50 from rising into the soil. Due to the combined action of friction forces with the ground on the disk furrow maker 51 and the pushing force that the control device 40 acts on the rack 52, the depth of penetration of the disk furrow maker 51 and the coulter 560 is ensured and, consequently, the depth of the application of the agricultural substance to the soil.

In a variant not shown in the figures, the resilient element 60 with the compression spring 61 is replaced by an elastic element of a different type. For example, the compression spring 61 is replaced by a tension spring, for example, mounted on the other side of the posts 31 and 42 relative to the axis 43. To adjust the tension of the tension spring, a tension adjusting device such as a screw is provided. This tension adjustment device allows you to adjust the length of the tension spring. This makes it possible to adjust the position of the tension spring in a similar way to adjusting the position of the compression spring 61 using the adjusting screw 62 and the pin 65.

The compression spring 61 can also be replaced by a torsion spring or a torque tube described below. For example, a torsion spring or torque tube may be mounted around pivot pin 43 between strut 31 and strut 42. For example, the torque tube may be in the form of an elastomeric torsion element shown in FIG. 3 US patents 6454019 B1. Such a torque tube comprises a rigid outer sleeve, an internal rigid insert, and a plurality of elastomeric beads located between the sleeve and the insert. In this case, the sleeve can be fixed on one of the posts 31 or 42, while the casing is fixed on the other rack 42 or 31. Rotation of the sleeve and the casing relative to each other leads to compression of the elastomeric rollers. Since the strut 31 forms a fixed support for the torque tube, the compression of the elastomeric rollers allows the torque tube to exert a pressing force on the strut 42 similar to the compression force generated by the elastic element 60. If necessary, a tension adjustment device, such as a lever system, in which the lever can be locked in different positions relative to the rack 31 (in two, three, four or more positions), allows you to adjust the pressing force of the torsion spring or torque tube on the rack 42.

Instead of or in addition to the elastic element 60, the second pressing force application means 13 may comprise a device with a removable weight(s). For example, a device with removable weight(s) contains one weight. The number of loads is not limited and may vary, for example, it may be equal to two, three, four or more. In this case, you can change the weight by adding or removing one or more weights. When the device with removable weight(s) contains multiple weights, it is preferred that all weights have the same shape and the same mass. In a variant, at least the first weight has a shape and/or mass different from the shape and/or weight of at least the second weight.

In yet another embodiment, not shown in the figures, the column 52 is pivotally mounted directly on the pivot shaft 43 between the column 31 and the column 42 so that the pivot shaft 43 is the common pivot axis for the control device 40 and the soil spreader 50 relative to the bracket 30 , while the control device 40 can still be rotated about the axis 43 independently of the device 50 to apply to the soil.

In yet another embodiment, not shown in the figures, the depth setting device 70 comprises a stop other than the helical stop 71, such as a screw-adjustable stop.

In yet another embodiment, a second disc furrower is provided on the soil applicator 50 . Alternatively, the disc furrower 51 is replaced by a coulter. In yet another alternative, the coulter 56 is configured to simultaneously cut the earth, independently open the furrow 6 and introduce agricultural substance into it.

Where possible, the various aforementioned options can be combined with each other, in particular when they are associated with different elements.

Claims (10)

1. The unit for applying an agricultural substance to the soil for an agricultural machine, made with the possibility of a fixed installation relative to the agricultural machine, while the unit for applying to the soil contains a control device (40, 41) and a device (50) for applying to the soil, and the control device (40 , 41) is configured to rest on the ground in the working configuration and serve as a depth positioning control element for the soil application device, and the soil application device (50) is configured to apply the agricultural substance to the soil in the working configuration, while the control device (40, 41) is made with the possibility of articulated installation directly on the support (11, 12), which is fixed relative to the agricultural machine, characterized in that the control device (40, 41) is made with the ability to act with weight (P) on the device (50) for introducing into soil in working configuration by means of stop (14) located between the post (42) of the control device and the post (52) of the soil application device, while the control device (40, 41) forms the first means of applying the pressing force to the soil application device (50). 2. The unit for applying to the soil of claim 1, while the unit (10; 20) for applying to the soil contains a second means (13; 60) for applying a pressing force, while the second means (13; 60) for applying a pressing force is configured to apply force pressing (F) on the control device (40, 41), while the control device (40, 41) transmits the pressing force (F) to the soil application device (50) in the working configuration. 3. The soil application unit according to claim 2, wherein the second pressing force application means (60) allows adjustments (33, 331, 65) to change the pressing force (F) that the second pressing force application means (60) acts on. to the control device (40, 41) in working configuration. 4. The unit for applying to the soil according to one of paragraphs. 2 or 3, in which the second means (13; 60) for applying a pressing force comprises an elastic element (61) configured to act with a pressing force (F) on the control device (40, 41) in the operating configuration. 5. The soil application unit according to claim 4, in which the elastic element (60) is adjustable in position relative to the control device (40, 41) and / or relative to the support (11, 12) fixed in relation to the agricultural machine, and / or tension adjustable. 6. The unit for applying to the soil according to one of paragraphs. 4 or 5, in which the resilient element (60) comprises a compression spring (61), a torsion spring, an extension spring, or a torque tube. 7. The unit for applying to the soil according to one of paragraphs. 1-6, comprising a depth setting device (14, 70) configured to adjust the depth of soil application by the soil application device (50) with respect to the control device (40). 8. The soil application unit according to claim 7, in which the depth setting device (70) comprises an adjustable stop (71), while the adjustable stop can occupy at least two different positions, each of the two positions corresponding to the depth of application to the soil agricultural substances by the device (50) for introducing into the soil, while the adjustable stop (71) is preferably a helical stop. 9. Unit introduction into the soil according to one of paragraphs. 7 or 8, in which the depth setting device (14, 70) is provided between the post (42) of the control device (40, 41) and the post (52) of the soil spreader (50). 10. An agricultural machine containing a unit for introducing an agricultural substance into the soil according to one of paragraphs. 1-9.

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