WO2016086918A1

WO2016086918A1 - Beam adjusting mechanism for a soil-working tool

Info

Publication number: WO2016086918A1
Application number: PCT/DE2015/100505
Authority: WO
Inventors: Georg Achten; Johannes BODEWIG
Original assignee: Lemken Gmbh & Co Kg
Priority date: 2014-12-02
Filing date: 2015-11-30
Publication date: 2016-06-09
Also published as: DE102014117668A1; EP3226673A1

Abstract

Disclosed is a beam adjusting mechanism (2) which comprises a rotating, eccentric securing bolt (8) and which allows the angles of the beam (4) and of the soil-working tool (3) that is attached thereto to be adjusted in a simple manner.

Description

DESCRIPTION

Grindel setting of a tillage tool

The invention relates to a Grindeleinstellung a tillage tool according to the preamble of claim 1.

Equipment for tillage have a frame, with which individual tillage tools spaced from each other by the soil surface to be processed are performed. The connection between frame and tillage tool is accomplished by a support arm or a Grindel. In order to set different angles of attack of the soil working tool, adjusting means are known to intermediate frame and arm or Grindel. For example, the German utility model DE 20 2012 002 916 U1 shows a holding arm of a rotating disk tool, which can be adjusted about a pivot axis relative to the frame. In this case, further recesses are arranged concentrically to the pivot axis, in which a certain arm position can be staked or fixed to the frame. A basically similar device is known from German Utility Model DE 7 835 771 U. Again, the arm movement takes place about a pivot axis relative to the frame. By two interlocking, opposing eccentric bushes, which engage in a second recess of the arm, an arm movement can be accomplished concentrically about the pivot axis. Both solutions have the most critical arm cross-section a recess for receiving a clamping screw. With constantly changing or oscillating load, as occurs on a soil cultivation device, there threatens a loss of soil cultivation tool. Remedy a generally larger arm cross-section or a local reinforcement, but which are more expensive, difficult or expensive to manufacture. The object of the invention is to provide a Grindeleinstellung for different employment of a tillage tool, which avoids the disadvantages described above and is inexpensive to manufacture and is practically set.

This object is solved by the features of the characterizing part of claim 1.

By arranging a Grindelprofile with preferably rectangular cross-section in a guide slot, which has at its Grindelprofilaustrittsende a Grindelprofil matching outlet cross-section, a Grindelführung is created, which does not require a critical strength recess in the Grindelprofil in critical bending region of the Grindels, namely at the outlet cross section of the guide slot. An eccentric safety bolt secures the grinder against being pulled out of the guide slot. The recesses required for the securing bolt are arranged in the middle region of the guide slot or end of the grind and thus outside the bending-critical Grindel cross-section. By rotating the eccentric securing bolt takes place in cooperation with the outlet cross section of the guide slot, which is in particular formed by two lateral stops, an angular adjustment of the grind relative to the outlet cross section of the guide link. The superimposed, translational movement of the grind relative to the outlet cross section of the guide slot is negligible and amounts to a maximum of twice the amount of eccentricity of the locking bolt. The adjusting mechanism shown here is similar to a crank mechanism, in which the eccentric locking bolt, the crank, the Grindel the connecting rod and the guide slot is the sliding guide of the connecting rod. The instantaneous, translatory movement of the Grindel recess runs on the trajectory, which completes the eccentric of the locking bolt around the pin axis. Since the Grindelausnehmung is spaced from the lateral stops of the guide slot, the Grindel performs during the rotation of the locking bolt at the same time the desired angular movement relative to the guide slot By using the securing bolt as the only translational motion security of the grind to the guide slot in the direction of the Grindelprofils a cost-effective and easy adjustment is created without securing the Grindel with further manipulation or funds against longitudinal displacement.

By a multi-part design of the securing bolt whose manufacture or assembly can be further simplified. For example, the eccentric can be pushed with an off-center bore or recess on the bolt axis.

By a positive or non-positive, rotational fixation of the locking bolt in several orientations meaningful adjustment positions of the grind can be specified relative to the guide slot. For example, the securing bolt can be lifted with a cross pin against spring force from a cross backdrop and be positively lowered in another position in this. Other, the locking bolt, for example, form-fitting or non-positively encompassing locking means are conceivable.

Due to the approximate, axial alignment of at least one lateral stop of the grind in the guide slot, which is formed for example by a cross-sectional edge at the outlet cross section of the guide slot and is aligned with the penetration of the tillage tool in the ground, there is an optimal angle adjustment of the tillage tool in the penetration without a significant, translational displacement of the tillage tool associated with it. In this case, the axial orientation represents an imaginary straight line, which cuts through a lateral stop and runs approximately parallel to the axis of rotation of the securing bolt to the ground surface and into the penetration region of the soil working tool.

By assigning the grind setting to the end of the grind to which the tillage tool is attached, an attack angle adjustment may be made in close proximity to the tillage tool.

By assigning the Grindeleinstellung on the tillage tool opposite Grindelende, namely the frame side, a setting of the eccentric safety bolt conveniently above the soil surface.

Due to the movable mounting of the Grindeleinstelleinrichtung about a pivot axis relative to the frame of the harrow, a further degree of freedom for the movement of the soil working tool is created. Preferably, the orientation of this pivot axis is horizontal or vertical to the ground or transverse to the direction of travel.

If the Grindel or its adjustment device is equipped with an overload protection, the grindel or the soil working tool can avoid an obstacle when hitting it, without deforming or destroying the adjustment device or the grindel. The overload protection can be done in conjunction with the aforementioned pivot axis via a spring or energy storage, which is arranged at a distance from the pivot axis, as well as a simple shear pin. An elastic or resilient mounting within the Schwenkache is conceivable.

If the Grindel is resilient or elastic, this itself assumes the function of an overload protection or can support by its resilient action a soil reduction effect of the soil working tool, for example in the form of a leaf spring.

The Grindeleinstellung has proven to be very helpful and effective in particular in conjunction with share tools, plow tools or rotating about an axis disc or spade tools to quickly and easily set different angles of attack of the aforementioned tools. The invention is characterized in particular by the fact that a stable Grindelführung is provided in a guide slot for a tillage tool, whereby by simple rotation of an eccentric locking bolt a simple attack angle adjustment of the tillage tool in several stages or continuously.

Further details and advantages of the subject invention will become apparent from the following description and the accompanying drawings, in which a Embodiment with the necessary details and individual parts is shown. Show it:

1 is a side view of a soil cultivating device,

2 is a perspective detail view of the Grindeleinstellung,

3 is a partial perspective view of the Grindeleinstellung,

Fig. 4 is the view like Figure 3 with another grind layer and

Fig. 5 is a design proposal of the locking bolt. FIG. 1 shows a towed tillage implement 1, which is pulled and / or carried by a towing tractor 22 with an upper link 24 and two lower links 23. The links 23, 24 are movably coupled to the machine frame 20. Likewise, a drawbar hitch suspension is conceivable. The harrow can be an adjustable support roller o.ä. to follow the depth guidance of the tillage tools. Of the machine frame 20 laterally two transverse tubes 21, 21 ', which are spaced apart in the direction of travel and fixed or movable with the machine frame 20 are connected. At regular intervals bearing pockets 26 are arranged side by side on the respective transverse tubes 21, 21 '. Transverse to the direction of travel about the axis 18, the guide slots 5 are pivotally mounted and held by the overload protection 19 in the position shown. From the guide slots 5 Grindel 4 are led out to the rear. This group 4 are bent down and each hold a soil working tool 3, which is in engagement with the bottom 25. The tillage tools 3, here for example serrated hollow discs, are rotatably mounted via a bearing 27 at the lower end 16 of the grind 4 via a screw. Likewise, clamping or wedge connections are conceivable. The axis of rotation of the bearing 27 is oriented slightly obliquely upwards and forwards in the direction of travel to ensure cutting and mixing of soil material. This provides for the tillage tool a characteristic cutting angle, which is to be adjusted depending on the nature of the soil, working depth and soil cover appropriate Holscheiben tools in particular around the vertical axis. The successive, front and rear tillage tools are aligned right and left in the direction of travel. Other orientations and arrangements are also possible.

Figure 2 shows a detailed perspective view of Grindeleinstellung 2 with the essential components. Transverse to the direction of travel and parallel to the ground extends a cross tube 21, to which a bearing pocket 26 is exemplarily arranged. To its parallel to the cross tube 21 extending axis 18, the guide slot 5 is pivotally mounted upward and is held by the overload protection 19 in the position shown. In this case, the overload protection 19 consists of a held by a frame-side abutment energy storage, here for example a coil spring which spaced from the axis 18, the guide slot and thus Grindel 4 and tillage tool 3 biases in the ground direction with a force. With an internal stop tab, the guide slot is held in the end position shown and can move upwards in case of overload. Other energy storage such as hydraulic cylinders, etc. are conceivable. The guide slot 5 consists of a rectangular, rearwardly tapered cavity in which the frame 4 is inserted with its matching rectangular cross section from the rear. By the rear stops 10, 1 1 of the guide slot 5 of the Grindel 4 is delimited translationally in its lateral movement, and it can in the same plane of movement with its front end 17, which protrudes into the backdrop, swing back and forth. The guide slot 5 has a lower and upper cover 28, 29. In the central region of these covers 28, 29 recesses 6 are introduced in the form of a bore. In these recesses 6, a securing bolt 8 is inserted from below, and secured at the top with a washer and a self-locking nut as securing means 30 against falling out. Likewise, the safety pin 8 can be inserted in a different position and secured with other securing means against loss or automatic adjustment. Here is not visible in the Grindel 4 also a recess 7 in the form of a Inserted bore through which the locking bolt protrudes. Through this connection between the securing bolt 8, guide slot 5 and 4 Grindel and the respective recesses 6, 7 of the Grindel 4 is set in conjunction with the rear stops 10, 1 1 and the covers 28, 29 of the guide slot 5 against unwanted movement. The lateral stops 10, 1 1 may be housing edges or surfaces of the guide gate 5, as well as spacer tubes, or similar elements which are inserted, clamped or inserted between the upper and lower covers 28, 29. Also a one-sided storage is possible. In this case, the safety pin 8 with its securing means 30 assumes a clamping effect. The rear stop can cooperate as a one-piece bolt in conjunction with an elongated, second outbreak of the grind 4, although the Grindel 4 is weakened by this second outbreak in the bending cross section if necessary. The safety pin 8 has in the region of the grind 4 via a rotationally symmetrical, eccentric surface, which is done by rotation of the locking bolt 8 about its own axis of rotation 12, a displacement of the grind within the guide slot 5 corresponding to the eccentric distance a of the locking bolt 8. The axis of rotation 12 extends through the recesses 6 of the guide slot 5. The axis 13 forms the rotational symmetry axis of the eccentric locking bolt 8 with distance or eccentricity a to axis 12. The axis 13 passes through the concealed recess 7 of the grind 4. An angular change of Grindelendes 17 in the guide slot causes the other Grindelende 16 a change in cutting angle of the attached tillage tool 3. The change in angle takes place about one of the two stops 10, 1 first The translational movement of the grind 4 in Grindelrichtung 9 is negligibly small and has no appreciable effect on the work of the tillage tool 3. The vertical alignment of the stops 10, 1 1 aligned at least approximately with the penetration portion 36 of the soil working tool, as by the axial alignment 35 shown or indicated. The axial alignment 35 preferably runs parallel to the Axles 12 and 13 and thus perpendicular to the plane of movement of the grind 4 within the guide slot 5.

Figure 3 shows the essential components for the interaction between the guide slot 5 and Grindel 4. The guide slot 5 is pivotally mounted in the bearing pocket 26, which is welded or bolted to the cross tube 21. The securing bolt 8 is inserted from below into the recess of the guide slot 5. The axis of rotation 12 of the recesses of the guide slot 5 and the axis of rotation 13 of the recess 7 of the grind 4 and the eccentric locking bolt surfaces are thereby by the amount a in the direction of travel shifted to the left. As a result, the Grindel 4 or its front end 17 is pivoted about the stop 10 and 1 1 to the left.

Figure 4 shows the same situation as Figure 3. However, the eccentric portion of the locking bolt 8 is pivoted with the offset a in the direction of travel to the front. The Grindel 4 is moved about the amount a forward and takes a mean angular position within the guide slot 5 a. If you want to turn the eccentric locking pin 8 clockwise further to the right, and the Grindel pivots about the stop 10 and 1 1 in the direction of travel to the right and takes the other extreme angular position. By skillful selection of the stop positions 10, 1 1 is obtained when turned backwards securing bolt 8 another, for example, fourth angular position of the grind 4th

In Figure 5, the eccentric safety pin 8 is shown. Concentric about the axis 12, the bearing surfaces 14 and 31 are arranged. Offset eccentrically by the amount a, the surface 15 is arranged rotationally symmetrical about the axis 13. The axes 12 and 13 are thus also separated by the distance a from each other. The bearing surfaces 14 and 31 are mounted in the corresponding recesses 6 of the guide slot 5, the surface 15 in the recess 7 of the grind 4, as described above. To tilt the To avoid securing bolt 8 in the recess 7 of the grind 4, the shape is not cylindrical, but executed crowned or with different diameters over the height. Concentric with the axis 12, a further surface extension 32 is arranged at the upper end for receiving a securing means 30, for example a thread for receiving a self-locking nut. The lower collar 33 of the securing bolt 8 forms the axially effective stop surface against the lower cover 28 of the guide link. The collar 33 is designed with a square in a standard wrench size. Likewise, a hexagon or another form is conceivable. Thus, a fast rotation of the locking bolt can be done without much effort. According to the aforementioned forms a circumferential groove 34 is recessed in the collar 33, which represents an anti-rotation against the guide slot in interaction with a resilient stop. Here, for example, a wire spring engages in the groove, which is resiliently secured to the guide slot. This results, for example, four or six locking positions corresponding to the aforementioned collar shapes. Likewise, the securing bolt 8 may be provided with a further actuating or actuating handle. Similarly, in the safety pin 8, a transverse pin or the like may be arranged, which is incorporated for example in a cross groove of the guide link. A spiral spring between securing means and guide slot allows an axial deflection of the pin from the cross groove to rotate the locking pin. Instead of the cross groove other recesses or Arretierungsformen are conceivable.

REFERENCE LIST

Harrow

Grindelwald setting

Tillage tool

Grindelwald

guide link

Recess (leading edge)

Recess (Grindel)

safety bolt

Grindelwald direction

attack

axis

Rotationally symmetric surface

Grindelwald end

axis

Overload protection

frame

cross tube

tug

handlebars

ground

bearing pocket

camp

cover

securing means

Rotationally symmetric surface

area

Federation

groove

Axial alignment

penetration region

Claims

PATENT CLAIM Grindel setting of a soil tillage implement

1. Grindeleinstellung (2) of a soil cultivation tool (3) with a Grindel (4) for inclusion in a guide slot (5) of a harrow (1), wherein the Grindel (4) and the guide slot (5) at least one rotationally symmetrical recess (6, 7) transversely to the profile Grindel have, which are aligned approximately parallel to each other, wherein a securing bolt (8) is provided which in the recess (6, 7) inserted the Grindel (4) radially to the rotationally symmetrical recess (6) of the guide slot (5) secures against movement, wherein in the gripping direction (9) spaced from the recess (6, 7) lateral stops (10, 11) of the guide slot (5) are arranged, which the grinder (4) rotatory about the axis (12, 13) of a recess (6, 7) limit in its movement,

characterized,

the securing bolt (8) has at least two rotationally symmetrical surfaces (14, 15) which correspond to the recesses (6, 7) of the frame (4) and guide slot (5) and which are offset eccentrically with an offset (a) relative to one another, wherein the grinder (4) upon rotation of the securing bolt (8) performs a translational movement relative to the guide slot (5), which in the region of its recess (7) perpendicular to the radial alignment of the eccentric offset (a) about the axis (12) of at least a recess (6) of the guide slot takes place.

2. Grindeleinstellung claim 1,

characterized,

that the securing bolt (8) forms the only translational motion safety of the grind (4) to the guide slot in the direction (9) of the Grindelprofile.

3. Grindeleinstellung according to claim 1 or 2,

characterized,

that the securing bolt (8) is designed in several parts.

4. Grindeleinstellung according to any one of the preceding claims,

characterized,

in that the securing bolt (8) is rotationally fixable in a plurality of orientations in a form-locking or force-locking manner.

5. Grindeleinstellung according to any one of the preceding claims,

characterized,

in that the axial orientation (35) of at least one lateral stop (10, 11) is aligned approximately with the penetration area (36) of the tilling tool (3) into the ground (25).

6. Grindel setting according to one of the preceding claims,

characterized,

in that the trimming adjustment (2) is associated with the one end (16) of the trellis to which the soil working tool (3) is attached.

7. Grindel setting according to one of the preceding claims,

characterized,

in that one grilling end (16) is associated with a soil cultivation tool (3) and the other, frame side gripper end (17) is associated with the grindel setting (2).

8. Grindeleinstellung according to any one of the preceding claims,

characterized,

the frame setting (2) is pivotably mounted on the frame side about a further axis (18), preferably oriented transversely to the direction of travel.

9. Grindeleinstellung according to any one of the preceding claims,

characterized,

that the frame setting (2) is equipped with an overload protection (19).

10. Grindeleinstellung according to any one of the preceding claims,

characterized,

that the frame (4) is resilient or elastic.

11. Grindel setting according to one of the preceding claims,

characterized,

that the tillage tool (3) assigned to the end of the grind (4) is a coulter, a plow tool or else a rotating disk or spade tool.