DE2716642A1 - Soil working implement with box shaped tool carrier - has tines fixed to ends of support arms and consisting of vertical bearing pins - Google Patents

Abstract

The soil working implement consists of a box-shaped tool carrier which has one or more adjacent soil working tools on its underside. These tools consist of support arms, which are driven about vertical axes of rotation. Tines are fixed to the ends of the arms and can move about parallel axes. Each tine consists of vertical bearing pins picked up by the support arm. A downwards projecting block connects to the bearing pin and accepts tools of the tines which are releasably fixed. The tool is fixed to the block via a over-head safety device.

Description

Tillage implement

The invention relates to a soil cultivation device, consisting from a box-shaped tool carrier, which on its underside with an or several adjacent soil processing tools is cutlery, which consists of support arms exist, which are forcibly driven in rotation around approximately vertical axes of rotation are and at their ends tines movably attached to axes running parallel thereto are.

Tines arranged in this way are automatically controlled by the soil, so that the lowest possible circumferential force is required.

There are testicle processing devices known in which on the support arms freely rotatable knife-shaped prongs are arranged.

They have a considerably larger extent in the direction of rotation than perpendicular to it. These prongs each have a cutting edge on their front side and adjoining parallel blade-shaped guide surfaces.

F. in tines shaped like this steers itself automatically in the ground, However, due to his relatively large guide surfaces, he is not able to To avoid pod components such as tree roots or stones in the noxa, so that a severe wear and tear and frequent damage to the tines cannot be ruled out is.

It is the object of the invention to overcome the disadvantages of the known prongs Avoid zii by making them easily replaceable and equipped with an overload protection device are.

This object is achieved according to the invention in such a way that each prong consists of a vertically running bearing pin received by the support arm, which is followed by a downwardly protruding investment block of one or more detachably attached knife-shaped tools that hold the prongs.

These and other features of the invention are illustrated in the drawings and explained in the following description.

1 shows a top view of the testicle processing device, FIG. 2 shows a front view of the soil cultivation device, FIG. 3 shows a side view of a Soil cultivation tool, FIG. 4 is a top view according to FIG. 3, FIG. 5 is a side view an embodiment of the tine, FIG. C a further embodiment according to FIG. 5.

The pod processing device shown in the figures consists from a box-shaped tool carrier 1 lying transversely to the working direction 10, which is equipped with soil cultivation tools 4 on its underside. The tillage tools 4 are arranged side by side at approximately the same distance and are forcibly revolving around approximately upwardly directed axes of rotation 5, wherein the trajectories 35 of the prongs 9, for example, ripping into one another Overlap.

The tool carrier 1 has a mounting frame on its front side 16. This consists of two side parts 23 and is provided with connection points, with which he to the lifting linkage 15 of a tractor 17, consisting of lower and Upper links 214 and 25 can be coupled. The drive of the tillage tools 4 takes place via the transmission 13 from the tractor 17 with the interposition of a PTO shaft.

The tool carrier consists of several interconnected box-shaped Frame parts 6, which have the same cross-section and individually only one part the total length, i.e. the working width of the tool carrier 1. The frame parts 6 consist essentially of jacket-like GehEusen31, the end faces of which go through Flange plates 12 are complete. The flange plates 12 of adjacent frame parts 6 are, for example, joined together by means of screws with the interposition of sealing material and point in the working direction 10 during soil cultivation. The flange plates 12 or their contact and sealing surfaces are machined and preferably Executed in a greater material thickness than the housing 31 itself sufficient rigidity of the tool carrier 1 even for larger working widths guaranteed. Furthermore, smooth contact and sealing surfaces are formed that prevent soil parts from entering. At the outer ends is the so formed Tool carrier 1 closed by cover 11.

According to the illustrated embodiment, a box-shaped Frame part 6 has one, two or four soil cultivation tools 4, their drive elements e.g. gear wheels 7 grip through the flange plates 12 of adjacent handle parts 6 and work together functionally. The tillage tools 4 are of Shafts 2 carried and driven to rotate around the upwardly directed axes of rotation 5, each with an opposite direction of rotation to the adjacent shaft 2. The The directions of rotation are shown in FIG. 1 by the arrows 8. The drive of the Waves 2 takes place via the gears 7, which lie next to one another in the tool carrier 1 on of the shafts 2 are attached, with only one, approximately In the fleet of the tool carrier 1 lying shaft 2 with the output shaft of the (; etriehes 13 is connected or forms a unit. At the bottom find the shaft 2 is each a support arm 3 is attached, which protrudes on both sides with the same distance. At the ends of the support arms 3 3, the prongs 9 are fastened in Ilillsen 314 in such a way that daiz they stick down with their tips.

Fig. 3 shows a soil cultivation tool) in the side view. In the position ei 32 there is a prong 9 looking in the direction of rotation 8 pictured. In the illustration at 33, the pin 9 is 90 degrees out of the direction of rotation escaped. According to the invention, a prong 9 consists of a head part 26 and a Working part 27. The head part 26 is supported by a vertically extending bearing pin 18 formed, which is followed by a contact block 19 downwards. The op parts 26 are received in their many number with the bearing pin 18 of sleeves 34, the are located on the free customer of the 'bracket arms 3 and by means of bearing bushes 29 to vertical axes 20 are rotatably mounted. The vertical axes 20 run parallel to the axes of rotation 5 of the pod processing tools 14. The bearing journals 18 are z.D. fixed by adjusting rings 21 within the sleeves 34 in the axial direction. At the downwardly protruding Eritle of each bearing pin 18 closes an axial Bearing surface 22, which is formed by the contact block 19 and is attached to the lower The end face of the llillse 311 or the bearing bush 29 is applied.

The Anlaeklötze 19 are used for the direct connection of the or Working parts 27 with the head parts 26. The working parts 27 are preferably made from one or two knife-shaped tools 28 each the contact blocks 19 have several contact surfaces 36 and 37 and at least one each Mounting hole 38 and, if necessary. one further hole each; 39 to accommodate the overload protection devices, for example consisting of a shear pin 40. The knife-shaped tools 28 have holes 38 and 39 analogous to the bearing blocks 19 and are used in the Assembly z.P.

applied to the contact surfaces 36 and 37 by screws 41.

Furthermore, they have cutting edges 14 on the front sides, which are extend over the entire freely protruding, downward-facing area.

Some exemplary embodiments of the prongs 9 are shown in FIGS. 3 to 6 shown. Fig. 3 shows a tine 9, in the front view and in the side view, The prong 9 is provided with two parallel to each other and to the vertical axis 20, Knife-shaped tools28 which are spaced apart from one another are equipped. The tools 28 have a fastening bore 38 and another bore at their upper ends 39 for receiving a shear pin 41. The shear pin 41 ensures in the event of overload a pivoting of the tools 28 (dashed illustration 42 in Fig. 3). The cutting edge 14 of the tool 28 extends in an approximately vertical direction in such a way that that it includes a downwardly open angle 30 with the vertical axis 20, which is less than 30 degrees and is preferably 15 degrees. The cutting edge 14 is located is at least partially behind the vertical axis when viewed in the direction of rotation 8 20. In the example shown in FIG. 3, the back of the tool runs 28 parallel to the cutting edge 14.

In Fig. 4 and Fig. 5 there is a further embodiment of a tine 9 shown. Here, the knife-shaped tool has 28 in the side view the shape of a trapezoid in the area of the larger cross-sectional area on the contact block 19 is present. In particular, the contact surfaces 36 and 37 are enlarged and the transverse stability of the knife-shaped tool 28 is increased, in particular at difficult ground conditions the guidance in the ground is improved.

The enlarged contact surfaces 36 and 37 ensure a simple, fastening consisting only of a screw 41, as shown in Fig. 6, the tool 28 with its upper end face on the widened contact surface 37 supports. Fig. 6 also shows a tine 9, in which the entire cutting edge 14 of the knife-shaped tool 28 is arranged behind the vertical axis 20, in order to improve the automatic control of the tine 9 in the soil.

Claims (9)

Claims 1. Soil cultivation device, consisting of a box-shaped Tool carrier, which on its underside with one or more juxtaposed Soil cultivation tools are equipped, which consist of support arms that are approximately vertical axes of rotation are forcibly driven revolving and at their Ends of the prongs are movably attached to axes running parallel thereto, thereby characterized in that each prong (9) consists of a vertically extending from the support arm (3) recorded bearing pin (18) is on which a downward protruding The contact block (19) is followed by the one or more detachably attached knife-shaped Tools (28) of the prongs (9) receives. 2. Soil cultivation device according to claim 1, characterized in that that the knife-shaped tool (28) with the interposition of an overload protection device. is attached to the plant block (19). 3. Floor processing device according to claims 1 and 2, characterized in that that the overload protection is designed as a shear pin (40). 4. Soil cultivation device according to claims 1 to 3, characterized in that that the knife-shaped tool (28) is fastened with only one screw (41) and is supported on the shear pin (40) or the contact surface (37). 5. Soil cultivation device according to claims 1 to 4, characterized in that that the knife-shaped tool (28) on its front side with a cutting edge (14) is equipped. 6. Soil cultivation device according to claims 1 to 5, characterized in that that the cutting edge (14) extends over the free downwardly protruding area of the knife-shaped Tool (28) extends. 7. Soil cultivation device according to claims 1 to 6, characterized in that that the cutting edge (14) forms an angle (30) with the vertical axis (20), which is less than 30 degrees and is preferably 15 degrees. 8. Soil cultivation device according to claims 1 to 7, characterized in that that the cutting edge (14) is at least partially behind as seen in the direction of rotation (8) the vertical axis (20). 9. Soil cultivation device according to claims 1 to 8, characterized in that that the cutting edge (14) is completely behind the vertical as seen in the tjml: tuft direction (8) Axis (20) lies.