GB2023384A - Soil cultivating machine - Google Patents

Abstract

A soil cultivating machine has a frame 1 and a plurality of rollers 8 in a line that are adjustable in the up and down direction with respect to the frame by pivoting support arm 9 about bolt 11 and securing it by inserting bolt 14 through a selected hole in row of holes 13, this adjustment being facilitated by the provision of handles 48 for moving the rollers. The proximal ends of adjacent rollers are supported by a common stub shaft 41 (Figure not shown). <IMAGE>

Description

SPECIFICATION Soil cultivating machines This invention relates to soil cultivating machines.

In known soil cultivating machines provided inter alia, with at least one roller which is adjustable in a direction of height with respect to a frame of the machine, particularly in machines having a large working width, the roller can often be adjusted in the direction of height only with difficulty.

According to the present invention there is provided a soil cultivating machine having a frame and a plurality of rollers which are adjustable in a direction of height with respect to the frame, the rollers being disposed in a line transverse of the intended direction of operative travel of the machine and each having at its ends a handle for moving the roller in the up and down direction.

A construction as just defined facilitates adjustment of the rollers in the up and down direction to a marked extent since handles are provided by which the rollers can be moved in the up and down direction.

For a better understanding of the invention and to show how the same may be carried into effect reference will now be made, by way of example, to the accompanying drawings, in which: Figure 1 is a schematic plan view of a first form of soil cultivating machine, Figure 2 is a side view of the machine of Figure 1, taken in the direction of arrow II in Figure 1 and drawn to a larger scale, Figure 3 is sectional side view, on a still larger scale, taken on line Ill-Ill in Figure 1, Figure 4 is a sectional side view taken, on a larger scale, on the line IV-IV in Figure 2, Figure 5 is a sectional viewtaken on line V-V in Figure 4, Figure 6 is a view in the direction of arrow VI in Figure 5, Figure 7 is a view in the direction of arrow VII in Figure 5, Figure 8 shows on an enlarged scale and in section a bearing for the facing ends of two neighbouring rollers, Figure 9 is a sectional view taken on line IX-IX in Figure 4, Figure 10 is a schematic plan view of part of a second form of soil cultivating machine, and Figure 11 shows on an enlarged scale and in section a bearing forthe facing ends of two neighbouring rollers of the machine shown in Figure 10.

The soil cultivating machine illustrated in Figures 1 to 9 has a hollow frame portion 1 extending transversely of the intended direction of operative travel A of the machine and made-up of two identical parts clamped together along longitudinal rims. Packing material is sandwiched between these longitudinal rims and the parts are clamped together by bolts 2.

The frame portion 1 supports substantially vertical shafts 3, forming parts of cultivating members 4. The longitudinal centre lines of the shafts 3 are preferably spaced apart by a distance of 15 centimetres and during operation they are slightly inclined forward, preferably at an angle of about 5 to the vertical. Each of the cultivating members 4 is provided with only one tine 5, which is fastened by means of bolts 6 to a carrier 7 located at the lower end of the shaft 2 which projects out of the frame portion 1. Behind the cultivating members 4 there are three supporting members 8 in the form of rollers, which have identical structures and are supported in a pivotable manner with respect to the frame portion 1 by means of arms 9 and 10 with one arm 9 at each end of the frame portion 1 and the two arms 10 intermediate the arms 9.Each arm 9, 10 is pivotable and can be fixed in a selected one of a plurality of positions with respect of the frame portion 1. The outermost arms 9 are pivoted by means of bolts 11 directly behind the lower part of the frame portion 1 to upwardly directed plates 12 extending in the direction of travel A and closing the ends of the frame portion. The plates 12 extend beyond the rear of the frame portion 1 and each has near its rear edge a row of holes 13 located on the arc of a circle having its centre on the longitudinal centre line of the bolt 11 (Figure 2). By means of a bolt 14, which can be passed through a hole in an arm 9 and through a selected one of the row of holes 13, each arm 9 can be set in position.The arms 10, located between the ends of the frame portion 1 and supporting the proximal ends of the respective rollers 8, are pivoted by bolts 15, whose longitudinal centre lines are in line with those of the bolts 11, between upwa rdlyextending plates 16 (Figure 3). Near the rear edge of each plate 16 there is a row of holes 17 located on the arc of a circle having its centre on the longitudinal centre line of the bolt 15. Through a hole in the arm 10 and any one of the holes 17 a bolt 18 can be passed to set the arm 10 in position with respect to the frame portion 1. Each plate 16 is secured to a support 19 which is clamped by means of the bolts 2 against the lower part of the frame portion 1.The top of each plate 16 and each support 19 is in engagement with a plate 20 of substantially triangular shape, viewed in plan, which is clamped by the bolts 2 against the upper part of the frame portion 1.

Each of the arms 9 and 10 has just behind its centre downwardly extending plates 21 which are substantially at right angles to the arm and which are secured in place on both sides of the arm (Figures 2, 4 and 8) by means of bolts 22. The plates 21 on each outermost arm 9 carry a stub shaft 23 supported in two relatively spaced ball bearings 24, the outermost of which bears on a shoulder 25 of the stub shaft.

These bearings are accommodated in a bearing housing 26 which is held in aligned apertures in the plates 21 and the arm 9. The bearing housing 26 is held in place with respect to the plates 21 by means of a dust cap 27 at the outboard end of the stub shaft 23, and by being located in a recess in a screening hood 28 located on the roller side. The dust cap 27 as well as the screening hood 28 are held in place by means of bolts 29, which also serve to secure in place spacer sleeves 30 located between the plates 21. On the side of the screening hood 28 the bearing housing 26 is closed by a labyrinth seal 31. The recess in the screening hood 28 for holding the bear ing housing 26 is located concentrically with the aperture for the stub shaft 23.Around this recess the wall of the screening hood 28 has a profile 32 which extends concentrically with the recess through 2700 from an outer end and then inwardly along another circular are through about 90 , the centre od this arc being spaced from the centre of the recess so that the profile terminates at an inner end located on the same radial line as the outer end with the two ends spaced apart from one another by a distance equal to about one quarter of the outside diameter of the screening hood (Figure 5).The wall having the pro file 32 has an outwardly inclined, bent-over rim. The portion 33 defined between the inwardly curved part of the wall having the profile 32 and the outermost periphery of the screening hood 28 as a whole is flat and is located at the level of the free edge of the bent-over rim (Figure 6). The radially extending front edge 34 of this portion 33 constitutes a scraping element, the function of which will be explained hereinafter.

The wall having the profile 32 extends inside the rim of a screen 35, which rim is bent over substan- tially at right angies to the remainder of this screen.

The screen 35 has a recess at its centre accommodating a bearing 36, formed by a ball-and-socket joint, on the stub shaft 23. A closing plate 37 for guarding the assembly of ball bearings 24 and the bearing 36 is held in place on the bearing 36 by a nut 38 cooperating with a screwthread on the inboard end of the stub shaft 23. The screen 35 is fastened by means of bolts 39 to the outer side of a supporting plate 40 located near the outboard end of the roller 8. The plate 40 has the shape of a six-pointed star (Figure 9).

The plates 21 on the arms 10 for supporting the proximal ends of the rollers 8 hold, in the case of each arm 10, a single stub shaft 41 intwo ball bearings 24 arranged in a bearing housing 42, which is held in place by means of screening hoods 28 on both sides of the supporting plates (Figure 8). The bearing housing 42 is closed on each side by means of a labyrinth seal 31. On both sides of the bearing housing 42 the stub shaft 41 has a ball-and-socket joint bearing 26 for supporting one or other of the rollers 8 and in the same manner as for the stub shaft 23 this bearing 36 is accommodated in a screen 35, inside which is located the wall having the profile 32 of the respective screening hood 28.The respective bearings 24 and 36 are arranged on the stub shaft 41 between closing plates 43, which are held in place by means of nuts 44 co-operating with screwthreaded ends of the stub shaft 41.

Near its centre each roller 8 has a further supporting plate 40 (Figure 1). Each tip of each of the three star-shaped supporting plates 40 of each roller 8 is cut and the severed parts 45 are bent over at right angles in opposite senses (Figures 4,8 and 9). The bent-over parts 45 thus provide V-shaped recesses 46 in which tubular, elongated elements 47 are secured around the circumference of the roller. Each tubular elongated element 47 runs along the length of the roller, with a slight kink near the centre (Figures 1 and 4) so that the elements are disposed in substantially a helical fashion around the circumfer ence of the roller in the manner illustrated in the Figures. The parts 45 permit simple and easy fasten ing of the respective elongated elements by welding during manufacture.

Rearwardly projecting free ends 48 of the arms 9 and 10 supporting the rollers 8 serve as handles that can be used for displacing the rollers 8 in a direction of height so that setting the arms 9 and 10 in position is considerably facilitated.

Inside the hollow frame portion 1 each of the shafts 2 of the cultivating members 3 is provided with a pinion 49 with the pinions on the shafts of neighbouring cultivating members drivably in mesh with one another. The shaft 2 of the cultivating member 3 near the centre of the machine Is prolonged upwards into a gear box 50, in which it is linked through a bevel transmission (not shown) to a shaft 51 projecting from the front of the gear box and connectable through an auxiliary shaft with the power take-off shaft of a tractor.

At the front the frame portion 1 is provided near the centre with a trestle 52 for attaching the machine to the three-point lifting device of a tractor. The top of the trestle 52 is provided with downwardly diverging supports 53; which are secured to the upper faces of the plates 20 so that an additional support forthecentral arms 10 is obtained.

The machine described above, having a working width of about 4.50 metres, operates as follows.

During operation the machine is hitched by means of the trestle 52 to the three-point lift of a tractor and from the power take-off shaft of the tractor the respective cultivating members 3 are driven through the transmission described above in a manner such that neighbouring cultivating members rotate in opposite senses. The tines 5 of neighbouring cultivating members work overlapping strips of soil. The effective depth of the cultivating members 3 can be set with the aid of the three rollers 8 disposed in a line transverse of the direction of operative travel A so as to be rotatable about a common transverse axis.For this purpose the arms 9 and 10, after removal of the bolts 14 and 18 respectively, can be moved about the hinge bolts 11 and 15 with the aid of the handles 48, in a direction of height, and can be fixed in the desired position with the aid of the bolts 14 and 18. The earth thrown to the rear by the cultivating members, the shafts of which, as stated above, are slightly inclined forward, is captured by the respective rollers 8 and evenly distributed, after which it is packed during deposition. During operation the bearings of the stub shafts 23 and 41 of the rollers 8 are protected against penetration of earth and the like, since the screening hoods 28 detach any material that may penetrate within with the aid of the scraping element formed by the front edge 34 of the portion 33, the scraping element co-operating with the adjacent roller end and material being conducted away along the guide formed by the inwardly curved profile out of the stationary screening hood.

Jamming of the rollers during operation is thus effectively avoided in a simple manner, even if the working conditions are such that the machine is soiling heavily.

The machine of Figure 10 has a larger number of cultivating members 3 so as to have a working width of about 6 metres. With this machine four rollers 8 of the same design as those described above are arranged behind the cultivating members 3. The outermost arm 9 support in the same manner as described above the outermost ends of the outermost rollers. In this machine, however, the proximal ends of the rollers 8 are each supported by a separate stub shaft 54 and a separate arm 55 (Figure 11). The arms 55 are in contact with one another and have a kink at the level of the stub shafts 54 so that a space is formed for the interengaging flange-shaped ends of the stub shafts. Each of the stub shafts 45 is supported by means of a ball-and-socket joint bearing 36 in aperture in one or other of the arms 55.The bearings 36 are held in place by means of bolts 56 on screening hoods 28A arranged on the arms. These screening hoods are designed substantially like the screening hoods 28 already described and they also have a scraping element. The wall profile of each screening hood 28A extends inside the bent-over rim of a cast iron screen 57 each of which has a bearing housing 58 accommodating relatively spaced ball bearings 24 on the respective stub shaft 54. The ball bearings 24 are separated by means of a spacer sleeve 59 from the respective ball joints 36 and are held in place by means of a nut 60 co-operating with the screwthreaded end of the stub shaft 54. Each nut 60 is covered by a dust cap 61 bearing on the adjacent ball bearing and extending into the bearing housing 58. The screens 57 are fastened by means of bolts 62 to the outermost supporting plate 40 of the respective roller.In this machine the frame portion 1A is provided with a trestle 63 for attaching the machine to the three-point lift of a tractor, this trestle being fastened by means of supports 64 to the top faces of the plates 20 for holding the supporting arms of the proximal ends of the outer and inner rollers 8. Also this machine has handles for the supporting arms 55, designated by reference numeral 48A.

Since in the two machines described the rotatable support at the proximal ends of the rollers comprises a hinge joint formed by the ball-and-socket joint bearing 36, the support provided by the rollers is flexible and the machine can satisfactorily match the ground surface.

The support of the respective rollers8 illustrated in Figure 11 imparts a higher load resistance to the rollers, which is important for a machine of this width.

In each machine each screening hood has a form such that material penetrating into the interior of the hood during operation is conducted out of the hood.

Whilst various features of the soil cultivating machines that have been described, and that are illustrated in the drawings, will be set forth in the following claims as inventive features it is to be noted that the invention is not necessarily limited to these features and that it encompasses all of the features that have been described both individually and in various combinations.

Claims (21)

1. A soil cultivating machine having a frame and a a plurality of rollers which are adjustable in a direc- tion of height with respect to the frame, the rollers being disposed in a line transverse of the intended direction of operative travel of the machine and each having at its end a handle for moving the roller in the up and down direction.

2. Asoil cultivating machine as claimed in claim 1, wherein the handle forms part of a supporting arm provided at the end of the roller for supporting the roller.

3. A soil cultivating machine as claimed in claim 1 or 2, wherein a rotatable support for each roller comprises a pivotable joint.

4. A soil cultivating machine having a roller and rotatable support provided at one end of the roller, which comprises a pivotable joint.

5. A soil cultivating machine as claimed in claim 3 or 4, wherein the pivotable joint is formed by a ball-and-socket joint.

6. A soil cultivating machine as claimed in claim 5, wherein the ball-and-socket joint is arranged between one end of the roller and a stub shaft and a supporting arm.

7. A soil cultivating machine as claimed in claim 5, wherein the ball-and-socket joint is arranged between a stub shaft and a supporting arm.

8. A soil cultivating machine as claimed in claim 6, wherein the ball-and-socket joint is supported by means of a supporting plate provided near one end of the roller.

9. A soil cultivating machine as claimed in claim 8, wherein the stub shaft is supported by means of two relatively spaced ball bearings in a supporting arm.

10. Asoil cultivating machine as claimed in claim 9, wherein the ball bearings are arranged in a housing which is closed on one side by means of a labyrinth seal and on the other side by means of a dust cap.

11. A soil cultivating machine as claimed in claim 9 or 10, wherein the ball-and-socket joint and the ball bearings are enclosed between a shoulder on the stub shaft and a nut co-operating with screw-thread at one end of the stub shaft.

12. A soil cultivating machine as claimed in claim 11, wherein the nut is located on the roller-side.

13. A soil cultivating machine as claimed in any one of the preceding claims, wherein two adjacent rollers havetheirproximal ends supported by means of a common stub shaft.

14. A soil cultivating machine having two rollers disposed in a line transverse to the intended direction of operative travel of the machine and having their proximal ends supported by a common stub shaft.

15. Asoil cultivating machine as claimed in any one of the preceding claims, wherein near each end of each roller there is a screening hood that is provided with a scraping element that cooperates with the adjacent roller end so that material getting inside the screening hood during operation is conducted to the outside.

16. A soil cultivating machine as claimed in claim 15, wherein the screening hood forms part of the rotatable support for the roller.

17. A soil cultivating machine as claimed in any one of the preceding claims, wherein each roller comprises supporting plates each having at its circumference parts bent over in opposite senses and to which are fastened elongated elements provided at the circumference of the roller.

18. A soil cultivating machine as claimed in claim 17, wherein each elongated element is formed by a tube which is arranged in substantially helical fashion with respect to the rotary axis of the roller and which has a sharp bend near its centre.

19. A soil cultivating machine as claimed in any one of the preceding claims, wherein one roller adjustable in a direction of height is disposed behind a plurality of cultivating members supported in a frame portion and adapted to rotate about upwardly extending axes.

20. A soil cultivating machine as claimed in claim 19, wherein two rollers are disposed behind the cultivating members, these rollers being supported at their ends by means of arms arranged so as to be pivotable with respect to the frame portion.

21. A soil cultivating machine substantially as hereinbefore described with reference to Figures 1 to 9, of Figures 10 and 11, of the accompanying drawings.