SE526848C2 - Resilient tooth for soil working machine, has part at one end for preventing tooth from twisting when under strain in slanting position - Google Patents

Abstract

The tooth is secured at one end by a screw-nut joint to a beam extending in the machine cross-direction. A non-twistable part at this end of the tooth is used to prevent the tooth from twisting when placed under strain in a slanting position. This part is located at a distance from the screw-nut joint which is equal to less than half the contact area between the end of the tooth and the beam. The other end of the tooth is in contact with the soil, either directly or indirectly via a tool.

Description

Thus, the present invention solves all of the above problems by completely eliminating the pin attachment (see fi g. 1). The pin bracket is eliminated when the connection area of the spring is given a special design to be connected with a screw to at least one of the sides of the beam. This provides the advantage that storage of a particular article, such as a pin bracket, no longer becomes necessary.

This design together with a suitable nut / screw size provides a strong, stable, inexpensive and easy-to-assemble joint. The beam on which the spring pins are mounted can be a solid beam (flat iron), a hollow polygon (eg a square beam) or an open beam, such as a U-beam. The beam is provided with holes in suitable places. Screws are mounted in the holes.

These can suitably, especially for ergonomic reasons, be mounted in advance and the nut only inserted on the thread (in case a seat for the screw with open recess is used), so that the spring pins hang on the screw head in mounting position and then assume the correct position when the nuts are tightened to a predetermined tightening torque, which is advantageously done with lu fi or hydraulically driven tool. The holes in the beam can be given a nmt cross section, whereby the springs are mounted in predetermined positions. In some places, for example near a wheel of a machine, it may be compulsory for the farmer to adjust the position of the spring stick. This is to adjust the fi movement towards the wheel. This clearance may need to be changed as the nature and humidity of the soil change. The soil can also contain a varying amount of straw and other crop residues / weeds. When the device according to the invention is used with seed drills, the need to adjust the mutual distance of the seed beetles can be great. When this need exists, it is proposed that the hole be removed to the desired degree. The spring frame can also be mounted on a beam consisting of two elements.

The invention is described in more detail below with reference to the accompanying rhymes, which show preferred embodiments.

Fig. 1 is a partial perspective view of a prior art bracket for a spring pin, the end of which is passed through a slot in the bracket and is fastened by means of a screw / nut connection.

Fig. 2 is a cross-section through a beam of an agricultural machine, showing a first embodiment of a device according to the invention with a spring pin or similar fastening to the beam by means of a screw / nut connection.

Fig. 3 partially shows a view similar to that in fi g. 2 of the first embodiment in a tightened, mounted position.

Fig. 4 shows in part a view similar to that in fi g. 2 of the first embodiment in a position in which the dressing is placed in place, but not tightened.

Fig. 5 partially shows a view similar to that in fi g. 2 of the first embodiment in an almost tightened, mounted position. 10 15 20 25 30 35 526 848 Pl00O0 3 F ig. 6 partially shows a view similar to that of fi g. 2 of a second embodiment of a device according to the invention with a spring pin or the like.

Fig. 7 partially shows a view similar to that in fi g. 2 of a third embodiment of a device according to the invention with a spring pin or the like.

Fig. 8 partially shows a view similar to that in fi g. 2 of a fourth embodiment of a device according to the invention with a spring pin or the like.

Figs. 9a - c show a partial plan view of utför your embodiments of the spring pin or similar fastening area.

Corresponding details in the embodiments described below and shown in the rhymes have been given the same reference numerals.

I fi g. 2 shows a disc type beetle 1 attached to an agricultural machine (not shown). The seed beetle 1 is rotatably attached to a spring pin 2 with a substantially rectangular cross-section, at least at the end portion 3, which is detachably attached to a beam 4 arranged on the agricultural machine.

The spring pin 2 is of the type which forms a loop 5 around the beam and then, seen in the direction of travel, extends backwards towards a second end portion 6, which is attached to the seed beetle 1.

Other tools can also be another tillage tool such as a male / steel or the like. The spring pin can in these cases have a different curvature and thus a different overall shape, which for some special cases will be illuminated longer fi am. The beam 4 has a substantially rectangular cross-section with preferably radially formed longitudinal edges 4a and has a side 4b, against which the end portion 3 of the spring pin 2 abuts and is releasably fixed by means of a screw / nut joint 7, 8, where the screw is passed through the beam and opposite each other occupied holes 9a and 9b, see fi g. The holes 9a and 9b received by the beam are placed at predetermined mutual distances between each other along the beam 4. In several successive rows of spring pins 2 in the direction of travel (shown by the arrow 10 in Fig. 2), the holes 9a, 9b in the beams are distributed in such a way that the tools are placed in relation to each other in order to achieve a predetermined cultivation of the soil.

In a preferred embodiment of the invention, the spring pin 2 is bent or forged at the outer end 11 to form at least one locking lug 12 intended to abut against a side 4c of the beam 4. The locking lug 12 thus constitutes a support against rotation of the spring pin 2 laterally when cultivating the soil. The holes 9a and 9b are so placed along the beam 4 that the screw / nut joint 7, 8 is mounted asymmetrically (see the distances x and y in fi g. 3) in relation to the center line of the beam, i.e. closer to the outer end ll of the spring pin to give a better lever x to the screw in the normal load case. The lever x 10 15 20 25 30 35 Pl0000 4 closest to the locking lug is thus shorter than half the width of the beam 4. The distance x is less than half of the abutment surface of the other end portion against the intended cross beam. The abutment surface 4b is substantially equal to the actual abutment surface of the spring pin 2 plus at each end of the abutment surface considerable outward radii of the longitudinal edges 4a.

The screw head 13, screw screw nut 7, 8, which in this embodiment lies under the spring pin 2 in the mounted condition, can advantageously be provided with a button or a mark 14, so that the fitter can feel that the screw is correctly oriented when the spring pin is moved. in position above the screw.

Fig. 4 shows a spring pin with an open slot at the end 11 (see below in fi g. 9a).

The spring pin has been hung on the pre-assembled screw where the nut has only been inserted on the thread. It is very practical to be able to mount the springs in this way as the work steps can be divided and the workflow can be made ergonomically correct.

Fig. 5 shows a capercaillie stick in a nearly finished position. The bracket with the locking lug 12 creeps up in the correct position and fi edema is ñxxed. The locking lug of the spring closest to the end 11 may have an angle to the portion 3 of the spring pin 2 abutting the beam 4, which is less than 90 ° in order to provide an extra clamping against the beam and thus a firmer joint. This clamping effect can also be achieved in that the locking lug or locking lugs have a substantially concave shape along the width of the spring pin, which is weakly indicated in the embodiments of the end portion of different spring pins in fi g. 9 a-c below.

Instead, a bent or forged locking lug 12 at the end 11 can fi the pin 2, as shown in fi g. 6, be provided with a preferably welded or forged lock fl äris 15, which is positioned so that when mounted fi spring pin 2 ends up against the side of the beam 4 facing from the end 16 of the p pin 2, i.e. at the place where the spring pin first meets the beam 4 in the direction of its end 16. The distances x and y and thus the position of the lever x are in this embodiment reversed relative to the form of drying out according to fi g. 2 - 5. In this case too, a clamping of the locking edge can be arranged by an inclination of less than 90 ° of the edge towards the beam 4 or a concave shape of the surface of the edge 15 towards the beam 4.

I fi g. 7 shows an embodiment of a spring pin with a spring steel 17 fixed to the outer free end 18 and thus forms a harrow pin 19. The harrow pin 18 extends around the beam 4 (dashed), but is different from the spring pin 2 according to fi g. 2 -5 bent back at 20 so that the direction of travel according to the arrow 21 is the reverse. 10 15 20 25 30 35 01 k) \ __) \ CO .Is CO PlO000 5 I fi g. 8 shows a further embodiment of the bracket for a harrow pin 22 with a stainless steel 23 or similar attached to the free end. The harrow pin 22 is in this case bent in an arc 24 away from the beam 4 and then substantially in the downward direction towards the ground. The direction of travel is indicated by an arrow 25.

I fi g. 9a - c show some possible embodiments of the end of the spring pin with one or more locking lugs, which are arranged to abut against the side 12 of the beam 4 facing the direction of travel 10.

I fi g. 9a shows an end of a spring pin 26 where the blank is forged for increased width to the two locking lugs 27, 28. Between the locking lugs an open slot 29 is arranged, the inner end of which forms a seat 30, against which the screw sheath of a screw / nut joint (not shown) 7, 8 are intended to abut. Between the legs 31, 32 formed by the slot, at the outer ends of which the locking lugs 27 resp. 28 are bent or forged, the slot widens outwardly toward its opening to form a predetermined angle. The locking lugs thus also form an angle relative to each other so that the outer ends 33 and 34 of the locking lugs first come into abutment against the outside of a beam (not shown). In this way an extra clamping of the spring pin 26 against the beam is provided.

I fi g. 9a also shows two lines (A - A and B - B), which fasteners can advantageously be bent slightly in the direction of the surface which is intended to abut against the beam.

The bending is so adapted that the area above the screw head must be given a fi start against the beam in the untrained condition. The area can lie against the beam in the drawn condition.

It can also be so strongly bent or cuped so that even in the drawn condition there is a smaller distance to the beam above the screw head. The bending or scaling can have different geometric designs. The purpose of the bending is to ensure abutment against the beam at a distance from the center line of the skmven.

I fi g. 9b shows an embodiment of a fastening end of a spring pin 35 with a complete locking lug 36 and a hole 37 for mounting a screw / nut connection (not shown).

The blank of the spring pin 35 is forged to provide an increased width at the attachment end of a beam (not shown). The surface 38 of the locking lug 36 facing the beam can be concavely designed to, like the embodiment in Fig. 9a, provide an extra resilient attachment to the beam.

I fi g. 9c shows an embodiment of the fastening end of a spring pin 39 with a complete locking lug 40 and a hole 41 for mounting on a beam (not shown) by means of a screw / nut connection (not shown). Here too, the extra attachment can be achieved by bending the locking lug so that the ends 42 and 43 first come into contact with a beam (not shown) when tightening a screw / nut connection (not shown).

Regardless of how the hole is designed, the spring is consequently held by two clamping devices: 1. The connecting surface of the spring pin is made slightly concave in such a way that the part of the fi edge that lies over the screw head does not abut against the beam without a collar.. In this way, it is ensured that the outer parts of the connecting surface are pressed against the beam. This provides good stability and cooperates with the second clamping device. 2. The second clamping device locks the spring at a predetermined angle which is usually 90 'to the beam. When the spring is pressed up against the beam by tightening the nut, the outer part of the locking lugs closes against the edge of the beam and the screw, which in turn clamps against the edge of the hole. By giving the various parts the right dimensions and design, a very easy-to-assemble and strong connection is obtained at low cost. It is not absolutely necessary for the function of the joint to obtain a large preload against the heels. If, on the other hand, the dimension x exceeds the dimension y in fi g. 3, the spring can loosen gradually when the angle is not completely fixed.

The hole in the beam can be occupied in the part of the half of the beam which is next to the locking lug or the locking end, as it is advantageous that the lever behind the bolt is longer than the one in front, this is when the spring, which is often a spring pin, is broken back by ground resistance.

The force that breaks forward is usually only the recoil when the spring has passed an obstacle, such as for example a rock.

The locking lugs, which are suitably forged, are advantageously given such a design that the outermost end braces against the beam, which means that the angle is less than 90 °. This design provides the optimal angle eringen xering. To further improve the angular fixeration, the width of the kan can be increased in the connection area by forging out the open slit or notch and only punching the beard. This increases the width of the material and increases the distance to the outer surfaces of the heels. The slot or notch can suitably be given an increased width against the locking lugs to simplify the assembly and further increase the abutment surface at the outer area of the lugs. 10 15 20 526 848 PIOOOO 7 In order to rotate the screw, it is suitably given a combined round and square part immediately above the skull. A round part to avoid sharp corners in the spring connection area. It is important to avoid corners in this area as corners and ger a give stress concentrations where cracks start. On the opposite side, the screw is suitably given the shape of a half square. This provides a rotation lock in the eller edema slot or hole. It also provides the ability to mount the screw in square holes for use in other contexts.

The nut 8 of the screw 7 is given a design with an enlarged foot to allow a high tightening torque without deforming the nut side 4d of the beam for thinner-walled profiles. The screw can be specially adapted to provide an optimal connection when mounting in elongated holes. It is then an advantage if the screw has a flat part which connects to the flat surface of the hole towards the front (i.e. towards the locking lugs).

The slot or recess is practical from an assembly point of view. An alternative to the open slot is a hole. When mounting, you must hold the spring in one hand and mount the screw with the other. This design is possible, but involves an extra work step during assembly.

The device according to the invention can of course be further modified within the scope of the appended claims.

Claims (10)

10 15 20 25 30 35 526 848 PIOOOO 3 PATENTKRAV Device for an fi spring stick (2) or similar for an agricultural machine with a transverse beam (4), which device consists of a cross beam bracket (7, 8, 9a, 9b) for said fi spring stick (2), said fi spring stick having two ends , of which a first end portion (6) is arranged for tilling soil either directly or indirectly via a tool and of which a second end portion (3) is intended to be releasably fastened by means of said bracket (7, 8, 9a, 9b), k characterized in that it comprises on the second end portion (3) a torsionally rigid member (12, 15, 27, 28, 36, 40) intended to prevent rotation of said capercaillie pin (2) by any oblique loading of the same and at a distance (x ) screw / nut joint seat (30, 37, 41) arranged from the torsionally rigid member, said distance (x) being less than heel av of the abutment surface of said second end portion against the intended cross beam. Device according to claim 1, characterized in that said torsionally rigid member is a locking lug (12, 27, 28, 36, 40) formed by the outer end (1 1) of said end portion of said spring pin (2) (3) is bent substantially 90 ° relative to said abutment surface in the direction of said side surface (12) facing the intended beam towards the direction of travel (10). Device according to claim 2, characterized in that said locking lug (12, 27, 28, 36, 40) is bent more than 90 °. Device according to claim 1, characterized in that said torsionally rigid member is a locking lug (15), which is arranged, preferably welded, on the pin (2) at the abutment surface of said second end portion (3) facing away from the capercaillie pin ( 2) end (16). Device according to any one of claims 1 - 4, characterized in that said abutment surface (4b) is substantially equal to the actual abutment surface of the capercaillie pin (2) plus at each end of the abutment surface considerable longitudinal edges (4a) of outer longitudinal edges. Device according to any one of claims 1 - 5, characterized in that said screw / nut strap seat is constituted by the inner edge of a slot (29) arranged at the other end (11, 27, 29). 10 15 PIOOOO 9 Device according to claim 5, characterized in that said slot (29) widens in the direction of the outer ends (27, 28) of the slits of the slot. Device according to any one of claims 1 to 5, characterized in that said screw / nut strap seat (30) is a closed slot or a hole (37, 41) and consists of the part of the slot or hole which is facing away from the other end of said pin spring (2). Device according to any one of claims 1 - 5, characterized in that said screw / nut dryer seat (30) is a round hole (37, 41). Device according to one of Claims 1 to 9, characterized in that the abutment-rigid members (12, 15, 27, 28, 36, 40) of the pin spring (2) are concave or bent so that the outer edges of said torsionally rigid members first comes into abutment when tightening said crossbeam bracket (7, 8) to form a built-in clamping.