FI82919C - ANORDING WITH TELESCOPARMAR. - Google Patents

Description

1 82919

Device for telescopic booms - Anordning vid teleskoparmar

The present invention relates to a device for receiving lateral loads relative to the longitudinal direction of the boom, in particular in telescopic booms fitted to cranes or the like. The structure of the telescopic boom is divided into at least two parts that can be telescopically moved relative to each other. When more than two movable parts 10 are used, it is desirable to provide a uniform telescopic transfer between the parts. The invention is also intended to solve this problem.

Cranes with a considerable dimension are often required for loading and unloading work. In order to be able to carry out lifting work both near and far, crane booms are now commonly used, which are, for example, of the simple folding boom type. However, if necessary, large boom lengths require free space upwards to provide space for the 20 folding joints when the boom is folded for close-up work. Free space upwards is not always available e.g. due to the fact that surrounding objects and obstacles located high can be damaged. For example, a folding boom crane with a high folding boom joint cannot be used for thinning 25 forests, as such a boom structure would cause unacceptable frame damage to the remaining trees. In this case, it is preferable to use said telescopic crane boom with several telescopic steps. In order to carry out local work, the 30 different telescopic steps must not be particularly long, especially in a forestry machine, where the telescopic parts must not protrude backwards due to the risk of impact damage to nearby trees. However, in order to achieve a large dimension, several telescopic steps must be used.

DE 2 002 090 discloses a telescopic boom for a crane or the like. The boom consists of a hollow base boom with additional hollow 35 2 82919 booms moving inside each other. The booms are equipped with guide rails or guide devices. The guide rails are fitted to the side walls of the booms. The guide rails are U-shaped and their arms act as running or sliding surfaces and the part 5 between the arms acts as a support for the guide means.

Finnish application 840231 discloses a crane or similar boom. The boom comprises four elongate stiffener members connected by four substantially planar plates 10. The boom is diamond-shaped in cross section. The stiffener members of the inner boom section slide in the stiffener members of the outer boom section.

In practice, however, these crane boom-15 mirrors present problems that are difficult to solve, especially with regard to the torsional stiffness requirement. Essentially circular telescopic parts provide the best torsional resistance to weight. The clearances between the telescopic steps must be limited very precisely in both the radial and axial-20 directions. Furthermore, in the extended position, the overlapping bearing length between the telescopic parts is remarkably short, and this often causes major problems in overcoming the friction that has occurred with the plain bearings used so far. This situation is particularly relevant when 25: precision driving is required, where the movement must not be uneven.

The object of the present invention is to provide a solution to the above-mentioned problems. By using a special combination of roller and plain bearings 3Q, the invention has made it possible to solve the bearing, play and friction problems which have occurred before, in particular with circular telescopic parts.

The main features of the invention appear from the features of claim 1 of patent-35 '.

According to one embodiment of the invention, one of the telescopically movable parts is provided with at least two 3,82919 opposite trough-shaped tracks. The second telescopically movable part is provided with running members cooperating with said tracks. Said second part is also provided with plain bearings adapted to co-operate with the surfaces of the trough-like tracks, which surfaces are substantially at right angles to the surfaces with which the running members co-operate. At least one of the movable parts is formed by two or more parts connected to each other via trough-shaped tracks or alternatively via rails supporting said running members to form this part or alternatively parts. The running members are free-running bearing rollers adapted to co-operate with opposite surfaces on either of the gutter-like tracks.

Sliding bearings consist of plates adapted to slide along the gutter bottom surface of the respective gutter-like track. The rollers acting as running bearings are mounted on pins fixed to rails fixedly fitted in the slotted grooves at the ends of said inner and outer parts.

When the telescopic boom thus shaped is used as the lifting arm, it is preferable to load it in such a direction that the running members receive lateral lifting forces with respect to the longitudinal direction of the arm, while the sliding bearings receive other lateral forces. This achieves the best torsional rigidity as well as smooth movement in precision driving.

3Q Where the extent of the telescopic boom in the retracted position must not be too great, the boom may preferably consist of three or more parts which are telescopically displaceable relative to each other. In order for the parts to move uniformly with respect to each other, the telescopic boom 35 'may have a special guide in the form of a roller chain or the like.

4,82919

Embodiments of the invention will be explained in more detail with reference to the accompanying drawings.

Figure 1 shows the telescopic boom in a partial section and 5 seen from two mutually perpendicular directions.

Fig. 2 shows on an enlarged scale, in a manner similar to Fig. 1, the bearings marked in the latter figure.

Figure 3 is a cross-section through the telescopic boom in the collapsed position.

Fig. 4 shows, like Fig. 3, a cross-section through the telescopic boom in the collapsed position, the boom having three bearing rails distributed at an angle of 120 ° to each other.

The telescopic boom 1 shown consists of three tubular parts 2, 3 and 4 which are telescopically movable with each other and have a circular cross-section. The outer tube 2 is 2Q arranged to surround the central tube 3, which in turn is arranged to surround the inner tube 4. The central tube 3 consists of two tube halves 3a, 3b, each of which has an opposite edge 3c welded to two I-beam rails 5 each forming two troughs 5a, 5b, which are turned inwards and outwards, respectively, in the central tube thus assembled, see Fig. 3. Similarly, in one embodiment, additional rails 6 and 7, respectively, are arranged in the slots 2a, 4a of the outer and inner tube ends, respectively. the distance from the facing ends of the outer tube 2 and the inner tube 4, respectively.

Holes 6a are formed in the rails 6 for bearing pins 8, which are fastened to the holes with a lock adapter. The free ends 9 of the pins 8 35 'are rotatably mounted on rollers 10, so that the circumferences 10a of the rollers 10 are arranged in tight rotational contact with the flanges 5c of the u-troughs 5, see e.g. Fig. 3. The rollers 10 are fixed axially with screws

II

5 82919 11 by means of plates 12 which at the same time form a sliding bearing guide with the outwardly turned troughs of the outer tube 2 and the central tube 3 on the one hand and the inwardly turned troughs 5 of the inner tube 4 and the central tube on the other hand. at an angle to the surfaces 5c with which the running members 10 cooperate.

In an alternative embodiment of the telescopic boom shown in Fig. 3, in addition to the central tube 3, an outer tube and / or an inner tube are also assembled from two halves of the tube. In this case, the halves are connected to each other, for example by welding, via elongate rails 15, which are similar to the rails 6 and 7 described above. The additional rollers 10 can thus be fitted to the rails 6 and 7 for guiding the central tube 3. This embodiment is often preferred because the tubes of suitable dimensions for thick telescopic booms are so large that they are difficult to manufacture in one piece and difficult to handle. The diameters of the different pipes are of the order of 450, 370 and 300 mm when viewed from the outer pipe. The thickness of the material is about 8 mm. As a starting material, it is easier to use a rolled thick sheet which is bent in a few steps to the desired shape. This need not be circular, but each half of the tube may have a number of straight sections separated by bend marks.

The described embodiment can advantageously be used as a crane boom. In this case, the boom is oriented with respect to the lifting forces 30 so that the vertical forces directed laterally to the crane are received by the rollers 10 by means of roller friction, while the other side forces, i.e. the forces directed at substantially right angles against the lifting forces, are received by the sliding friction plates. with the telescopic parts 2, 3, 4 moving relative to each other. In this connection, it may be mentioned that the forces directed laterally with respect to the lifting forces are generally relatively small, but it is nevertheless important that these be received in such a way that the 6 82919 telescopic parts are not fixed relative to each other. The plain bearing bearing 12 can also be fixed in such a way that it is movable to a certain extent in order to suitably fit the plain bearing track 5. The plain bearing plates 5 can be made of, for example, Robalor®.

As shown in Fig. 4, instead of two diametrically arranged roller bearings and a plain bearing system, three of these can be arranged so that their mutual angular distribution is 120 ° and they are arranged parallel along the central tube 3. Thanks to this arrangement, both the rollers and the plain bearings efficiently absorb all bending loads, whatever they apply in any direction to the telescopic boom 1. In this example, the plain bearing function of the plates 12 is only secondary and the main function of the plates is thus axially fixed at the free ends 9. However, the parts are connected to each other completely untwisted and the structure is form rigid.

Again, one or more of the tubes 2, 3 and 4 may be formed from a plurality of parts similar to those previously described in connection with Figure 3.

2? In addition to the example shown with three telescopic parts, a larger number of parts can be used if necessary, since there is no risk of harmful play or frictional resistance when using the bearing solution of the invention.

The invention is not limited to the illustrated embodiment relating to roller control in guides. Here, too, various previously known e.g. systems formed by ball and roller bearing structures, albeit in a direct guide structure according to the idea of the invention.

Instead of the circular cross-section shown in the boom, the cross-section of the boom may be oval, triangular, quadrangular or in various ways polygonal.

35 li

Claims (9)

7,82919 A device for receiving lateral loads with respect to the longitudinal direction of a boom, in particular in telescopic booms for use with hoists and the like, comprising at least two telescopically displaceable parts, one part (3) of which is provided with at least two opposite, trough-like tracks (5a). , the second part (4) is provided with running members (10) for cooperating with said tracks, said second part also being provided with plain bearings (12) adapted to cooperate with the surfaces (5d) of the trough-like tracks (5a) at substantially right angles to those surfaces (5c) with which the running members (10) co-operate, and of which at least one of the movable parts (2, 3, 4) consists of two or more parts (3a, 3b) communicating with each other in the gutter-like tracks (5a) through or through the rails supporting said running members, part or parts in which the running members are formed by loosely running bearing rollers (10) adapted to co-operate with one of the two opposite surfaces (5c) of the trough-like tracks (5a), characterized in that the plain bearings consist of plates (12) adapted to slide along the gutter bottom surface (5d) of the gutter-like track (5a), and that the rollers acting as running members are mounted on pins (9) fixed to rails fixedly fitted to said inner and outer part (2, 4). ) and that said plates are fitted at the ends of the pins. 30 Device according to claim 1, characterized in that the trough-like tracks (5a) are arranged on diametrically opposite sides of said part (3) and that the co-operating running and plain bearing members (10, 12) are arranged in connection therewith. Device according to claim 1, characterized in that the number of trough-like tracks (5a) is three 8 82919 or more and they are arranged divided (Fig. 4) with respect to the geometry of the telescopic parts, the cooperating running and plain bearing members being arranged accordingly . 5 Device according to any one of claims 1 to 3, characterized in that said plates (12) are shaped so as to form a stop for the co-operating roller (10) and to have a shape suitable for adaptation to said track 10. Device according to any one of the preceding claims, characterized in that one or more of said plates (12) has a certain movable attachment for a suitable adaptation to said plain bearing track (5). Device according to one of the preceding claims, wherein the telescopic boom consists of three telescopically displaceable parts, an outer part, a central part 20 and an inner part, characterized in that the central part (3) is provided with trough-like tracks (5a, 5b) on both outer and inner sides , wherein the outer part (2) is provided on the inner side with running and plain bearing members (10, 12) cooperating with the tracks (5b) 25 on the outer side of the central part (3), and wherein the inner part (4) is provided on the outer side with running and sliding with plain bearing members (10, 12) cooperating with the tracks (5a) on the inner side of the central part (3). Device according to claim 6, characterized in that said tracks (5) have an H-beam-shaped shape for forming rails (5a, 5b), the rail flanges forming rolling paths for running members (10) and the web part forming slideways for said plates (12) for. Device according to one of the preceding claims, characterized in that the roller bearings (10, 5) are arranged 9 82919 so that they also receive the torsional forces occurring between the telescopic parts (2, 3, 4). Device according to one of the preceding claims, characterized in that the telescopically displaceable parts (2, 3, 4) consist of tubes having a circular shape or other cross-sectional shape.