SE501406C2 - Device comprising a frame and a member rotatably stored therein - Google Patents

Abstract

A device of the kind comprising a frame (1) and an element (2) rotatably supported therein includes a drive assembly (17) arranged at the frame (1), said drive assembly having an output drive axle (16) drivingly connected to a first end of the element (2). Means (18) are provided to support the drive assembly (17) relative to the frame and prevent a body (19) of the drive assembly to rotate relative to the frame. A bearing (20), which is provided for the output drive axle (16) and comprised in the drive assembly (17), is also arranged to function as a rotation bearing for the rotatable element (2) as a consequence of the latter being supported relative to the frame (1) via the output drive axle (16).

Description

15 20 25 30 35 501 406 conditions must exhibit very accurate straightness. Furthermore, double bearing devices are required, namely a first between the end piece and the frame and a second which is included in the drive assembly and which stores its output drive shaft relative to the body of the assembly.

SUMMARY OF THE INVENTION The present invention aims to reduce the disadvantages outlined above.

This is achieved by the feature of claim 1. Consequently, the shaft bearing in the drive assembly will serve as rotary bearing not only for the drive shaft but also for the rotatable element itself, thereby substantially simplifying the construction. Furthermore, the precision requirements regarding the straightness of the rotatable element are significantly reduced in that precision deficiencies that occur within certain limits are taken up by the fact that the body of the drive unit moves somewhat to the required degree in relation to the framework.

Further advantageous features and advantages of the inventive device are defined in the dependent claims and are dealt with in the following description.

BRIEF DESCRIPTION OF THE DRAWINGS With reference to the accompanying drawings, the following is a more detailed description of an exemplary embodiment of the invention.

In the drawings, Fig. 1 is a partially cut and schematic view showing a device according to the invention from the side, and 2 is an enlarged detail view of that illustrated in the circle indicated by Fig. 1 in II, 10 15 20 25 30 35 3 501 406 fi g 3 en view from the left in Fig. 1, however, a protection has been applied over the storage facilities, Fig. 4 is an enlarged detail view illustrating the contents of the circle indicated in Fig. 1 by IV, Fig. 5 is a view viewed from the right in Fig. 1, and Fig. 6 is a view illustrating a support member also extending in the frame of the framework with the drive unit of the device removed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT The device according to the invention comprises a framework generally designated 1 and at least one element 2 rotatably mounted therein.

As will be described in more detail below, the rotatable element 2 is formed by a main section 3 and at this end pieces 4 and 5, respectively. A device 6 is provided for holding the main section 3 and the end pieces 4, 5 together.

As can be seen from fi g 3, 5 and 6, in the present example in practice three rotatable elements 2 are intended to be used. The device according to the invention is primarily intended to be used as a disintegration device for different types of materials or goods, although other applications are also possible. With regard to the disintegration aspect, the device can then be based on the disintegration principle referred to in European Patent No. 81539. As indicated in Figures 3, 5 and 6, the three rotatable elements 2 are thought to be arranged triangularly with two upper and one lower. The two upper rotatable elements 2 can then cooperate with each other in the manner dealt with in the said European patent and the same also applies to the interaction between the lower rotatable element and one or both of the two upper ones. To the extent that the principle of disintegration according to the European patent is to be applied, the rotatable elements, in practice their main sections 3, must be provided with machining means 7 (see fi g l) with the character of threads. 10 15 20 25 30 35 501 406 4 This thus means that the rotatable elements 2 acquire the character of screws. However, it is emphasized that the device according to the invention may be provided with other types of processing means 7, such as strikes, teeth, discs, etc., operating according to other disintegration principles.

As illustrated in Fig. 1 with respect to the lower part of the rotatable elements 2, their main sections 3 are intended to have a tubular core 8, from which the machining elements 7 protrude. At both ends of the main section 3, transverse plate elements 9 are arranged, as indicated by dashed lines.

The framework 1 has at its ends ends 10 and 11, respectively, and between them extending, wall-like enveloping means 12 (ñg 5) so that the framework 1 will delimit an interior, in which the rotatable elements 2 extend between the ends 10 and 11. When disintegrating goods, this is intended to enter the framework 1 via an upper opening 13 thereof and the goods leave the framework through a lower opening 14. It is understood that to the opening 13 can be connected arbitrary input-facilitating devices, such as funnel formations, conveyors, etc. In connection with the At the lower outlet opening 14 from the framework, arbitrary material receiving devices, such as conveyors, containers, etc., can be located.

The three rotatable elements 2 present are equally designed in terms of storage and drive; therefore, only the construction will be described in more detail with respect to one of the elements, more specifically the bottom which in fi g 1 is illustrated in more detail.

At a first end 15 of the element 2, this is drivably connected to an output drive shaft 16 of a drive unit arranged at the frame 1, generally designated 17. As will be described in more detail below, there are means 18 for supporting the drive unit 17 relative to the frame. the frame 1 and prevent its frame 19 from rotating relative to the framework. A bearing for the drive shaft 16 included in the drive unit and schematically indicated is also arranged to function as a rotary bearing for the rotatable element 2 in that it is supported relative to the framework 1 via the drive shaft 16.

The means 18 for supporting the drive unit 17 relative to the frame 1 and in preventing the drive unit body 19 from rotating relative to the frame are arranged to allow a certain relative movement, including a certain angular position, between the body 19 and the frame 1. Expressed in other words thus formed means a coupling which is intended to allow both certain axial and certain radial movement of the drive unit body 19 in relation to the framework 1, wherein in addition the body 19 must be able to tilt somewhat as a consequence of freedom of movement in said coupling in adaptation to lack of straightness of the rotatable element 2.

The means 18 comprise, as is clearest from fi g 4, interlocking means 21, 22 of the frame 19 and the framework 1, respectively. These engaging means 21, 22 are designed as interlocking recesses and projections, respectively. It is then preferred that the recess means 21, 22 have a complementary shape-locking design in order to avoid rotation of the body 19 relative to the framework. More specifically, in the example, the engaging means 21 of the frame has the shape of an orange portion, which is received in the engaging means of the frame 1 designed as a recess 22. In the selected embodiment, the engaging means 21 of the body have the character of projecting projections with hexagonal periphery. This protrusion is received in the recess 22, which likewise has a hexagonal shape. It should be noted, however, that as shown in fi g 5, two of the sides of this hexagon with respect to the recess 22 are defined by portions included in projections 21 of the two adjacent drive unit bodies 19 so that they always abut each other along two sides of the hexagon while the other four the sides of the hexagonal recess 22 are defined by the framework 1.

It is further pointed out that the body 19 of the drive unit 17 at the hexagonal projection 21 also has an adjacent, cross-sectional circular portion 23 intended to be received in a circular space 24 (see fi g 6) in the framework 1. 10 15 20 25 30 35 501 406 As previously described, the portions 21, 23 of the frame 19 are received with such clearances in the corresponding portions 22, 24 of the framework 1 that any tolerances can be accommodated.

The example shows how the engaging means 22, 24 for the three drive units 17 are formed in a common carrier 25, which suitably has a disc-like structure closer to fram g 4-6. In operation, this carrier 25 is rigidly connected to the framework 1 and thus forms part thereof.

However, means 27 in the form of adjusting screws are intended to adjust the position of the carrier 25 relative to the end 10 of the framework 1. In this case, the end 10 is provided with brackets 26, which are provided with the adjusting means 27 intended to actuate the carrier 25 to the correct position. In the example, the adjusting means 27 consist of screws in threaded engagement with threaded holes in the brackets 26 and arranged to act with their ends on the carrier 25. There should be adjusting means for actuating the carrier 25 in at least two different directions. Furthermore, bolted connections 28 are intended to increase the position of the carrier 25 relative to the framework 1 when the carrier is set in an adequate position. The bolt joints 28 extend through holes in the carrier 25 and engage the brackets 26.

The means 6 for connecting the rotatable element 2 to the drive shaft 16 of the drive assembly comprise a drawbar 29. This engages in the example with the drive shaft 16 in that the drawbar comprises a threaded end screwed into a threaded hole 30 in the shaft 16. This has means, for example splines, one or several wedges or the like for rotatably connecting the drive shaft to a sleeve 32. Attached to this is a disc element 33. More specifically, screws 34 can serve for the attachment. The sleeve 32 and the disc element 33 together form the previously mentioned end piece 4. The disc element 33 has an opening 36 for allowing the passage of the drawbar 29 and further centering means 35 in the form of a shoulder 35 fitting together with a corresponding embodiment in the plate elements 9 of the main section 3 for the purpose of centering the main section 3 relative to the end piece 4.

As can be seen from fi g 1, the drawbar 29 passes through the end piece 5 located at the other end of the element 2 and has a threaded outer portion, with which a nut 37 engages. By tightening this nut 37 on the drawbar 29, the end piece 5 will be pressed against the adjacent plate element 9 of the main section 3 with a pivotable disc member therein so that the main section will in turn be pressed against the other end piece. 4, which in turn will be pulled by the drawbar 29 towards the end of the shaft 16.

As shown in Fig. 4, the portion 39 of the carrier 25 defining the opening 24 will form a restriction for the body of the drive assembly to move inwardly toward the frame 1. To limit the body of the drive means to move in the opposite direction, the carrier is arranged closest to of ñg 5 forward attack 40 which grips over the protrusion 19 of the frame 19 ns äns 21.

As can be seen from fi g 2, the rotatable element 2 is supported at its end facing away from the drive unit 17 relative to the frame 1 by means of a bearing device 41. More specifically, this is arranged to act as a bearing between the end piece 5 and a rigid frame 1, for example by welding, attached sleeve 42. The bearing device 41 projects at least partially into an annular space 43 between the end piece 5 and the sleeve 42.

The bearing device 41 comprises a bearing 44, which is arranged to prevent the end piece 5 from moving outwards from the framework 1 by abutting against a shoulder 45 on the end piece. The inner race of the bearing 44 restricts the inward movement of the end piece 5 towards the center of the frame by abutment against a stop member 46 which here is designed as a nut engaging with a thread on the end piece and locked against rotation by means of a lock washer.

The outer running ring of the bearing 44 is surrounded by a bearing housing 47. At the bottom of Fig. 2, a first alternative design of this bearing housing is illustrated, namely as being formed in one piece. In the upper half of fi g 2 an alternative design is illustrated where the bearing housing 47 'is formed by two annular parts 48, 49 vid xxed to each other by means of xxing means 50, for example screws. Irrespective of whether a one-piece or two-part design is chosen for the bearing housing 47, the same is arranged to be limited in its movement inwards to the right in the sleeve 42 by taking support against a shoulder 51. On the inside of the sleeve 42 51. 10 15 20 25 30 35 501 406 bearing cover 52 erar xers the bearing 44 radially outer running ring inside the bearing housing 47 by pressing the running ring in the direction to the right in fi g 2 against a shoulder formed on the bearing housing 47. The bearing cover 52 is fixed to the bearing housing 47. by means of screws 53. Also with regard to the bearing cover 52, two different embodiments are illustrated in Fig. 2, namely in the upper half a one-piece design of the bearing cover and in the lower half an embodiment where the bearing cover is formed by two mutual means. screws 56 interconnected parts 54, 55.

The bearing cover 52 is in turn fastened to the sleeve 42 by means of fastening means 57 in the form of screws.

An outer cover 58 is suitably arranged over the bearing cover 52.

Both the bearing device 41 and the end piece 5 are removable in the outward direction (arrow 59 in ñg 2) from the frame 1 through the sleeve 42 after the drawbar nut 37 has been loosened and thus the end piece 5 has been released from the main section 3 of the rotatable element 2 and also the bearing lid 52. Thus, the bearing device 41 with the attached end piece 5 can be slidably pulled out of the sleeve 42. A prerequisite for this is of course that the end piece 5 has no parts with a larger diameter than the inner diameter of the sleeve 42. Accordingly, the disc member 38 of the end piece 5 for coupling to the main section 3 must have a smaller diameter than the smallest diameter of the sleeve 42. A particularly preferred embodiment in this case is that in the composite state of the device said portion 38 of the end piece 5 is arranged to run radially inside and relatively close to an inner surface of the sleeve inwards in the frame with a peripheral surface 60, which is suitably cylindrical or almost cylindrical. end portion 61 for the purpose of limiting the passage of contaminants in the direction past the disc element 38 into the space indicated in fi g 2 by the reference numeral 43.

When mounting the device according to the invention, the drive unit 17 is placed in place in the carrier 25 and the end piece 4 of the rotatable element is pushed onto the drive shaft 16 from the inside of the end 10. Then the bearing device 41 and the end piece 5 are loosely inside the sleeve 42, after which the main section 3 is lowered inside the frame 1 and the drawbar 29 10 15 20 25 9 501 406 is applied so that it passes through the main section 3 and the end pieces. When the parts are located adequately in relation to each other, the nut 37 of the drawbar 29 is tightened in order to contract the main section 3, the end pieces 4, 5 and the shaft 16.

When starting the drive assembly 17, the drive shaft 16 will bring the element 2 into rotation. The drive bearing 17's own bearing 20 will thereby act as a bearing for both the shaft 16 and the element 2, whereby the position of the drive 19 of the drive unit 17 with some required clearance in relation to the frame 1 allows the relative movements between the frame 19 and the frame 1 which may occur. due to lack of straightness of the rotatable element 2.

Disassembly of the device is carried out in the reverse order, i.e. the drawbar 29 is loosened and the end piece 5 with associated bearing device 41 is retracted slightly according to the arrow 59 in fi g 2 (this can be facilitated by using the separation screws 62 indicated in fi g 2 suitable for pulling away bearing device 41 in the direction of arrow 59 from the framework 1).

Most importantly, the main section 3 of the element 2 can be lifted upwards inside the framework 1 for replacement or renovation. The bearing device 41 and the end piece 5 can also be pulled out according to the arrow 59 for service or replacement as a continuous unit.

It is a given that the described device can be designed in a number of alternative ways within the scope of the inventive concept. Although in the example the drive unit 17 is intended to comprise a hydraulic motor, which, possibly via a gear, drives the output shaft 16, any other types of motors can be considered.

Claims (10)

10 15 20 25 30 35 10 501 406 Patent claims Device of the type comprising a framework (1) and an element (2) rotatably mounted therein, which at a first end is drivably connected to an output drive shaft (16) of a drive assembly (17) arranged at the framework ) and which at a second end facing away from the drive assembly is supported relative to the frame (1) by means of a bearing device (41), means (18) being provided for supporting the drive assembly (17) relative to the frame and preventing a body ( 19) of the drive unit to rotate relative to the framework, characterized in that a bearing (20) included in the drive unit (17) for the output drive shaft (16) is likewise arranged to function as a rotary bearing for the rotatable element (2) in that this is pushed up the relative frame (1) via the output drive shaft (16), that the means (18) for supporting the drive unit (17) relative to the frame and preventing the drive unit body (19) from rotating relative to the frame (1) form a coupling arranged to allow both certain axial and certain radial relative movement, including a certain inclination, between the frame and the framework, and that the means (18) forming the coupling comprise interlocking means (21, 22) of the frame and the frame, respectively, which engaging means (21, 22) has a complementary form-locking design to avoid rotation of the frame relative to the framework. Device according to Claim 1, characterized in that the engaging members (21, 22) of the frame and the frame are designed as mutually engaging recesses and projections. Device according to Claim 1 or 2, characterized in that the engaging means (21) of the frame are designed as an orange portion, which is received in the engaging means (22) designed as a recess. Device according to one of the preceding claims, characterized in that a drawbar (29) engaging with the drive shaft is arranged to connect the soot 406 to the rotatable element (2) with the drive shaft (16) by - traction press the rotatable element (2) against the drive shaft (16). Device according to one of the preceding claims, characterized in that the engaging means (21) of the body (19) consist of a projection with a hexagonal periphery, which projection is received in a recess (22) of hexagonal shape. Device according to claim 5, comprising at least three drive units (17) with associated rotatably mounted elements (2), characterized in that two of the sides of a hexagon formed by a single recess (22) are defined by portions included in projections (21 ) of the frames (19) to two adjacent drive units (17) while the other four sides of the hexagon formed by the recess (22) are defined by the framework (1). Device according to any one of the preceding claims, comprising at least three drive assemblies (17) with associated rotatably mounted elements (2), characterized in that the engaging means (22) of the frame (1) designed as recesses for the three drive assemblies (17) are formed in a common carrier (25). Device according to claim 7, characterized in that the carrier (25) in operation is rigidly connected to the framework (1) and forms part thereof. Device according to Claim 7 or 8, characterized by means (27) for adjusting the position of the carrier (25) relative to an end (10) of the framework (1). Device according to claim 9, characterized in that the end (10) is provided with brackets (26), which are provided with the adjusting means (27), that the adjusting means (27) consist of screws in threaded engagement with threaded heels in the brackets (26) and arranged to act with their ends with the carrier (25), and that bolted joints (28) are intended to fix the position of the carrier (25) relative to the framework (1) when the carrier is set in an adequate position.