SE508815C2 - Device for anchoring an axle - Google Patents

Abstract

Device for the anchorage of an axle (1) at each of its ends, preferably in a pair of fixing lugs (2) or the like formed with through holes for the axle. The device is characterised in that at each end of the axle there is a guide bevel (1a) and at least one plane chamfer (3). The chamfers (3) form an angle with the longitudinal axis of the axle and are connected to the outer surface of the axle, leaving a cylindrical axle section between the plane chamfers. The device at each plane chamfer (3) comprises a body (4), with a form corresponding to the plane chamfered part of each axle end, together with a section, extended axially adjacent to the guide bevel at each axle end and having a segmental-shaped end (4a), which along its curve has a flange (4b), directed radially outwards past the periphery of the axle. The bodies are designed to act as wedges with points directed towards the cylindrical centre section. By means of screw elements (5, 6) a movement can be imparted to each body (4) in an axial direction towards the cylindrical section, thereby producing an anchorage of the axle (1) in each hole.

Description

sos 815 2 10 15 20 25 30 35 happen at both shaft ends at the same time, ie you have to hold the shaft, to prevent the shaft from rotating when tightening. Even with this solution, the strength at the shaft end is negatively affected. This solution also causes a relatively large axial projection past a fastening ear, which means that the shaft can be easily damaged so that its fastening is broken. Finally, it can be stated that this solution should have a very high manufacturing cost.

An object of the present invention is to provide a device of the initially meshed type, which gives the shaft ends good strength, which is to be able to anchor a shaft at its respective ends, in a pair of through-holes formed with through holes for the shaft. or the like, which device allows easy tightening by hand of one side at a time without resistance, which device can not be inadvertently removed from the shaft when it is placed in the earlobe and which device is furthermore simple and inexpensive both to manufacture and to maintain and which device entails such large free surfaces at the shaft ends that the required marking text can be applied there with good readability. The object has been achieved by a device which has the features stated in claim 1.

Preferred embodiments of the device also have one or more of the core features specified in the subclaims.

The device according to the invention has several advantages: Due to the fact that no mechanical deformation of the constituent parts is required during assembly, tightening can take place by hand, without special tightening tools.

Due to the flat sliding surface between the shaft and the body, complete abutment between the body and the shaft is obtained during the entire tightening process.

The complete bearing also means a greater freedom to choose larger wedge angles, which will facilitate a possible later disassembly.

The flanges at the circular segment-shaped end surfaces of the bodies will act as physical stops and prevent the shaft from falling out of the mounting ears.

In the event of a later disassembly, the lip on one side will support the earlobe and will be forced to split from the shoulder. The lip also provides the opportunity to use a gripping puller tool around this when disassembling. 10 15 20 25 30 35 508 815 3 Furthermore, the lip means that additional locking devices on the end surfaces and the mounting ears, respectively, become superfluous, which allows a minimal axial protrusion on the sides and a low cost.

Additional factors that positively affect the cost picture for the inventive device are that the device has few components, which are easy to manufacture and provide great flexibility.

The invention will be explained in more detail below with the aid of examples of embodiments of the present invention and with reference to the accompanying drawings in which: Fig. 1 shows an exploded view of a first embodiment of the device according to the invention in which the various parts appear.

Fig. 2 shows a section through a shaft, which is provided with the device according to the invention according to fi g 1.

Fig. 3 shows an exploded view of an alternative embodiment of the device according to the invention where two wedge elements are arranged at an angle of 120 ° between them.

Fig. 4 shows an end view of the device according to fi g 1 or fi g 2.

Fig. 5 shows an embodiment with a projecting portion surrounded by the guide phase, in which the head of the bolt is lowered, for extra protection against extreme impact.

Fig. 6 shows an exploded view of a desiccation mold with an axial bore made through the entire length of the shaft and a bolt arranged therein for the action of the bodies at both shaft ends.

For identical or analogous details, the same reference numerals are used when describing all fi gures.

Fig. 1 shows a first embodiment of a device according to the invention at a cylindrical shaft 1. The shaft 1 is arranged to be anchored at its ends, preferably in a pair of through-holes 2 or similar formed with through holes for the shaft (see fi g 2). At each shaft end there is a guide phase 1a, which facilitates the insertion of the shaft into the fastening ears 2. Furthermore, at each shaft end there is a chamfer 3, which is designed so that a plane substantially elliptical sissy 4 10 15 20 25 30 35 is formed between a cord at the shoulder end and the mantle surface of the shoulder. The sliding surface forms an angle ot to the longitudinal axis of the shaft. Between the flat chamfer 3 at the shaft ends there is a cylindrical shaft portion. When the shaft 1 is placed in the holes of the mounting ears, bodies 4 with a shape corresponding to the flat chamfered part of the respective shaft end and with a portion axially extended in connection with the guide phase 1a at the shaft end can be inserted therein, which terminates at a circular segmented end 4a. At the arc of the circular segment-shaped end there is a radially outwardly past the periphery of the shaft directed ns end 4b, which is arranged to act as a stop and prevent the shaft from learning the façade ears in the axial direction after it has been mounted. The bodies 4 are arranged to act as wedges with points directed towards the cylindrical cutting portion of the shaft. At the shaft end in the middle of the respective planar chamfer there is an internally threaded axial bore 5. A bolt 6 is to co-operate with the threaded bore 5, so that the head 6a of the bolt, when the bolt is screwed in towards the shaft end, will press against the circular segment shaped end surface 4a and thereby imparting to the body 4 a movement in the axial direction towards the cylindrical portion. The body will then move up the flat sliding surface at the shaft end so that it is thereby anchored in the fastening ear 2 by means of the wedge action.

Fig. 2 shows a section through the shaft 1, which is provided with the inventive device and placed in a pair of fixed ears 2 formed with through holes for the shaft. Since the device is the same at each shaft end, only one shaft end will be described. At the shaft end there is the guide phase 1a and the bevel 3, which retains the flat sliding surface. The sliding surface forms the angle ot to the longitudinal axis of the shaft. Between the flat chamfers at each shaft end there is the cylindrical shaft portion. After the shaft has been placed in the hole of the mounting ears, a body 4 has been inserted into the respective hole, the axial extent of which towards the cylindrical portion of the shaft is less than the axial extent of the mounting ear in the same direction.

The body 4 has in the section a wedge shape which corresponds to the flat beveled part of the respective shaft end and a portion axially extended in connection with the guide phase 1a at the shaft end, which terminates with the shaft 4b directed radially outwards past the periphery of the shaft. The flange 4b, when the device is mounted in this way, will act as a stop and prevent the shaft 1 from leaving the mounting ears 2 in the axial direction. At the shaft end, during the respective chamfer 3, there is the internally threaded axial bore 5. The bolt 6 cooperates with the threaded bore 5, so that the head 6a of the bolt, when the bolt 6 is screwed in towards the shaft end, will press against the body end 4a and press it upwards. the flat sliding surface, so that the shaft end is thereby anchored in the fastening ear 2 by means of the wedge action.

Figure 3 shows how a number of bodies 4 can be arranged at each shaft end in the case of large shaft diaphragms. These are then arranged in the same way as described in connection with fi g 1 and fi g 2. In the diagram it is shown how two bodies 4 have been arranged at each shaft end with an angle of 120 ° between them, so as to lock the fi one. distributed with equal division around the circumference of the shaft end.

Fi g 4 shows an end view of the device according to fi g 1 and fi g 2. This shows the circular segment-shaped end 4a of the body. At the circular segment-shaped end 4a there is the arc with the radius outwards 4b radially outwards beyond the periphery of the shaft, which is arranged to function as a stop and prevent the shaft 1 from leaving the mounting ears 2 in the axial direction. It is also shown here how at the shaft end, in the middle below the respective chamfer chord, the bolt 6 cooperating with the internally threaded axial bore 5, whose head 6a, when the bolt 6 is screwed towards the shaft end, will press against the circular segment-shaped end surface 4a and by imparting to the body 4 the movement in the axial direction towards the cylindrical portion, so that the shaft end can be vid xerated at the hole of the mounting ear.

Fig. 5 shows an alternative embodiment in which at the shaft end a projecting portion surrounded by the guide phase 1a carried out at the circumference is arranged, in which the head 6a of the bolt 6, shown here as an Allen bolt, is immersed. Through this design, the bolt 6 is given extra protection against extreme impact.

Fig. 6 shows how the shaft can be provided with an axial recess 5 formed through the entire length of the shaft, at the respective shaft end in the middle of the respective planar chamfer 3. A bolt 6 extends through this, which at a first end has a head 6a resting against the substantially circular segment-shaped end 4a of one body and at the other end has a nut 7 cooperating with a thread on the bolt, which rests against the substantially circular segment-shaped end 4a of the other body. In this way, the bodies 4 are arranged to be imparted a movement in the axial direction towards the cylindrical portion when the bolt joint is imparted to a tightening rotational movement. This design can have particular advantages as it is desirable to be able to pull the bolt joint from one side. Alternatively, the bolt 6 may be a pin bolt, which cooperates with two nuts 7, each resting against the respective substantially circular segment-shaped ends 4a.

It is obvious to a person skilled in the art that the invention is not limited to the embodiments described above, but that it can instead undergo modifications within the scope of the inventive strength defined in the appended claims. The device can, for example, be designed such that the bore 5 to some extent opens at the substantially circular segment-shaped ends 4a of the bodies so that a larger abutment surface against this is provided for bolt heads and nuts, respectively.

Claims (1)

Device for anchoring a shaft (1) at its respective ends, preferably in a pair of mounting holes (2) or gluing formed with through holes for the shaft, characterized in that in each shaft end has a guide phase (1a) and at least one planar chamfer (3), which forms an angle ot to the longitudinal axis of the shaft and connects to the mantle surface of the shaft, leaving a cylindrical shaft portion between the planar chamfers, the device comprising at each plane chamfer (3) a body (4), with a shape corresponding to the planar chamfered part of the respective shaft end and with a portion axially extended in connection with the guide phase at the respective shaft end with a substantially circular segment-shaped end (4a) and a radially outwardly directed circumference of the shaft (4b) along the arc of the circular segment-shaped end, the respective body (4) being arranged to act as a wedge with a tip directed towards the cylindrical portion and that the respective body (4) by means of screw means (5, 6) a movement in the axial direction towards the cylindrical portion can be imparted and thereby provide an anchoring of the shaft (1) in the respective holes. Device according to claim 1, characterized in that the angle is reached in the range 10-30 °. Device according to Claim 1 or 2, characterized in that the bodies (4) are made of a harder material relative to the shaft (1). Device according to one of Claims 1 to 3, characterized in that two chamfers (3) are formed at each shaft end at an angle of 120 ° between them and in that a body (4) with associated screw means (5, 6) is provided for each chamfer ( 3). Device according to one of Claims 1 to 4, characterized in that the screw means are arranged to act between the respective body (4) and the respective shaft end. Device according to claim 5, characterized in that at the respective shaft end, in the middle of the respective chamfer (3), there is an internally threaded axial bore (5) and a bolt (6) which is arranged to cooperate with it, wherein each bolt has a head (6a) which rests against the substantially circular segment-shaped end (4a) of each body and is thereby arranged to impart to each respective body (4) a movement in axial direction towards the cylindrical portion when the respective bolt (6) is imparted a rotational movement. Device according to one of Claims 1 to 4, characterized in that, as a screw means, an axial bore (5) made through the entire length of the shaft and opening at the respective shaft end in the middle of the respective planar chamfer (3) 6), the bolt at a first end having a head (6a) resting against the substantially circularly angled end (4a) of one body and at the other end of the bolt a nut (7) cooperating with a thread on the bolt, which rests against the other the substantially circular segment-shaped end (4a) of the body, whereby the bodies (4) are adapted to be imparted a movement in the axial direction towards the cylindrical portion when the bolt joint is imparted to an tightening rotational movement. Device according to one of Claims 1 to 4, characterized in that, as a screw means, an axial bore (5) formed through the entire length of the shaft, opening at the respective shaft end in the middle of the respective planar chamfer (3) and a pin bolt (5) extending therethrough. 6), wherein at the first end of the pin bolt there is a first nut (7) cooperating with a thread on the pin bolt, which rests against one substantially body-shaped end (4a) of one body and at the other end of the pin bolt there is a second co-operating with a thread on the pin bolt. nut (7), which rests against the substantially circular segmented end (4a) of the other body, whereby the bodies (4) are arranged to impart a movement in the axial direction towards the cylindrical portion when the bolt belt is imparted to tightening rotational movements. Device according to one of the preceding claims, characterized in that at the shaft end there is a projecting portion surrounded by the guide phase carried out at the circumferential phase, in which the head of the bolt is immersed.