DE102014212829A1 - shaft attachment - Google Patents

Abstract

The invention describes a shaft attachment, in particular for a transmission, with an inner region for placement on a shaft, an inner region opposite the outer region for functional transmission and at least one end region for axial support of the shaft extension, wherein the wave attachment is formed as a hollow cylinder.
It is proposed that the at least one end region has an adjacent, in particular adjacent, outer region at least partially axially projecting elevation, which increases a support radius of the shaft attachment on a counterbody.

Description

Shaft attachment, in particular for a transmission, with an inner region for placement on a shaft, an inner region opposite the outer region for functional transmission and at least one end region for axial support of the shaft extension, wherein the wave attachment is formed as a hollow cylinder

State of the art

It is already known from the prior art wave essays, which are arranged on shafts and clamped with nuts on the waves. The known shaft extensions are hollow-cylindrical, have at least one axial end region, which is designed for clamping the shaft extensions. The at least one end region of the shaft extensions is formed by a surface which, due to the production, is convexly curved.

Disclosure of the invention

The invention is based on the object with simple constructive measures a shaft attachment for a transmission of a machine tool, in particular a hand tool, in such a way that the rigidity of the transmission is increased.

The object is achieved with a shaft attachment, in particular for a transmission, with an inner region for placement on a shaft, an inner region opposite the outer region for functional transmission and at least one end region for the axial support of the shaft attachment. The wave attachment is designed as a hollow cylinder. In this case, the at least one end region on a neighboring, in particular adjacent, at least partially axially projecting to the outside elevation, which increases a support radius of the shaft attachment to a counter body.

The invention makes it possible to increase the rigidity of the transmission with simple measures. With simple means while a support radius of the shaft attachment is increased by the frontal area protrudes axially further on the outside than on the inside. As a result, an increased effective support radius is made possible, which is supported on a counter-body, such as on an inner ring of a ball bearing, at a maximum distance from an axis of the shaft extension. As a result, higher forces and moments can be absorbed with a radially acting force on the shaft attachment, since the radially acting forces do not split exclusively in a resulting bending stress of the shaft attachment, but also in an axially acting compressive stress of the shaft attachment. The larger the support radius, the stronger can be compensated for radially acting bending forces by axially resulting pressure forces. Thus, a multiaxial stress state of the shaft attachment is achieved, which leads to a homogeneous and improved stress state in the shaft attachment, since the stress is evenly distributed over the shaft attachment. Furthermore, the deflection of the shaft attachment is reduced by the end region according to the invention. Consequently, an increased rigidity is achieved, which is characterized in an increase in performance of the shaft attachment and an improved concentricity of the shaft attachment. Due to the reduced deflection of the shaft attachment is curved radially less, thus ensuring a defined function.

The wave attachment according to the invention is formed in one piece. In an alternative embodiment, the shaft attachment may also be formed in two parts or in several parts. The shaft attachment is hollow-cylindrical and has an inner region, an outer region and a front region. The inner region may be formed as an inner surface. The inner area is intended to set up the shaft attachment on a shaft and if necessary radially center. The outer region may be at least partially formed as a coaxial with the inner surface extending outer surface. Furthermore, the outer region may have a gear element, which is designed for a rotational transmission of the shaft attachment. The front region has an adjacent, in particular adjacent, to the outer region, in particular to the outer surface, extending survey, which is at least partially formed axially projecting. As a result, the end region can have a defined support region, which is designed to stiffen the shaft attachment and, in particular, the transmission. The shaft attachment can be placed on the shaft and axially clamped or clamped by a nut between a ball bearing, in particular an inner ring of a ball bearing, and a nut.

In this context, "wood-cylindrical" should be understood to mean an at least substantially cylindrical or conical body which is at least substantially formed by an inner region, in particular a bore. The hollow cylindrical shape of the wave attachment should thus be understood as a hollow cylinder-like or hollow cylindrical.

In this context, an "end region" is to be understood as meaning a region which extends at least partially transversely, in particular at least substantially orthogonally, to an outer region and / or an inner region and / or an axis of the wave attachment. Especially The region may extend radially to the outer region and / or the inner region. The front region may be formed as at least one end face and / or at least one support surface. The end face and / or the support surface may be formed obliquely to the outer region and / or to the inner region. The end region may have an end face and a support surface, which are arranged parallel to one another and are preferably offset from each other at least substantially in the axial direction. The end face may be at least partially formed as a support surface. The at least one support surface may be formed as an annular surface and connect to the outer region, in particular the outer surface. In this case, the support surface is formed at least partially axially projecting and provided for the axial support of the shaft attachment.

By "at least partially axially projecting" should be understood in this context, an end region having at least one contour which projects axially and limits an axial extent of the shaft extension. In this case, the end region, in particular a survey of the forehead region, at least partially protrude axially. The contour can be formed as an edge or as a corner. The contour can be designed as a taper. The contour can be formed as a surface. The contour may have a radius connecting adjacent surfaces.

The dependent claims indicate expedient developments.

It may be expedient that the at least one end region has a support surface adjoining the outer region and an end surface adjoining the inner region. In particular, the survey may have an annular surface as a support surface. Thereby, the support radius can be maximized and a flat support surface for supporting on a counter body, in particular an inner ring of a ball bearing, be formed. As a result, a deflection or a compliance is reduced and increases the rigidity of the shaft attachment. Preferably, the support surface of the end region is designed as, in particular annular, support surface. In particular, the support surface is arranged at least substantially parallel to the end face and offset axially relative to the support surface. Thus, it can be achieved that the end face does not touch the counter body, in particular the inner ring of the ball bearing. As a result, an increased support radius can be realized. Preferably, the end face is arranged obliquely to the support surface. As a result, a survey that is particularly easy to produce can be realized.

Furthermore, it is proposed that the end region of the inner region to the outer region in the axial direction of the forehead area pointing away, in particular at least partially, steadily increases, in particular at least partially, arcuately increases or, in particular at least in sections, increases abruptly. In this case, an "arcuate" an at least partially concave and / or at least partially convex portion can be understood. As a result, particularly advantageous stresses can be formed in the radial direction to the axis of the shaft attachment. Furthermore, weight can be saved.

Preferably, the support surface of the end region is designed as, in particular annular, support edge. Preferably, the end region is at least partially conical. This can ensure that a maximum support radius of the shaft attachment is introduced into the counter body. In particular, this can be formed in a particularly simple manner, a survey which is arranged adjacent to the outer region of the shaft attachment and allows a maximum support radius. Preferably, the end portion can be lowered by a countersink, so that a support surface is radially outboard with a maximum support radius and a transversely extending to the support surface end face is introduced.

Preferably, the survey on the support surface for supporting on a counter body.

Preferably, the survey, in particular the support surface, a radial extent of up to 70%, in particular up to 55%, preferably up to 40%, preferably up to 20%, particularly preferably up to 10%, of the thickness. Furthermore, the elevation from an outer area to an inner area is up to 70%, in particular up to 55%, preferably up to 40%, preferably up to 20%, particularly preferably up to 10%. This allows an optimal setting of the support radius. In particular, the support radius of the elevation of the end region can thereby be introduced as far as possible from an axis of the shaft attachment.

It is also proposed that the outer region has a gear element, in particular a helical gear. Hereby, the shaft attachment can transmit a rotational movement via the gear element. The gear member may transmit a rotary to a rotary or a translational movement. The gear member may be formed as part of a transmission. Preferably, the gear member is formed as a bevel gear, in particular a bevel gear. Preferably, the gear element is helically toothed. This allows the transmission higher forces and moments in both the axial and in transmitted radial direction. Furthermore, the stress state of the shaft attachment can be optimized, whereby the rigidity of the transmission is increased.

Preferably, the inner region has at least one recess, which is designed for the positive connection with a shaft or a feather key. This can be provided an advantageous solid positive connection between the shaft and the shaft attachment. Alternatively, another connection that appears reasonable to a person skilled in the art may be provided between shaft and shaft attachment.

The shaft attachment is preferably clamped, in particular by a nut. This allows an advantageous fixed axial clamping of the shaft attachment. In particular, by using a nut, a defined biasing force can be applied to the shaft attachment. Thus, by the biasing force, a first stiffening of the shaft attachment and introduced by the axially projecting end portion having an increased support radius, a second stiffening in the shaft attachment.

Brief description of the drawings

Further advantages emerge from the following description of the drawing. In the drawings, embodiments of the invention are shown. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations. This shows

1 a perspective view of an angle grinder or a grinder,

2 a sectional view of the first embodiment of the shaft attachment,

3 a sectional view of a second embodiment of the shaft attachment and

4 a sectional view of a portion of a transmission according to the prior art.

In the figures, the same components are provided with the same reference numerals.

The 1 shows a hand tool, such as a known angle grinder 100 or cut-off grinder 100 with a grinding wheel 101 or a cutting disc 101 , The angle grinder 100 has a known transmission with a shaft 2 (in 4 shown) and a gear stiffening inventive shaft attachment 1 on. The grinding wheel 101 or the cutting disc 101 is at the angle grinder 100 or the cut-off grinder 100 arranged and is thereby by an output shaft (not shown here) of the angle grinder 100 or the cutting grinder 100 driven.

The 2 shows a first embodiment of the wave attachment according to the invention 1 , The wave tower 1 is formed as a hollow cylinder and has an axis a. The axis a forms the symmetry axis of the shaft attachment 1 , The wave tower 1 includes an interior area 3 , one inside 3 opposite outdoor area 5 and two forehead areas 7 ,

The following figures each refer to the shaft attachment 1 , in particular for connection to the shaft 2 , The wave 2 and the wave tower 1 are rotatably formed about an axis a and may be provided to translate a rotary motion into a rotational and / or a translatory motion. The wave tower 1 is with the wave 2 detected and axially via a nut 35 fixed. The wave tower 1 is preferably in an angle grinder 100 or a cut-off machine 100 installed. The wave tower 1 is designed to a gear of the angle grinder 100 to stiffen. The transmission can be designed as a bevel gear.

The interior 3 is as an inner surface 9 , in particular as a cylindrical inner surface 9 , educated. The interior 3 is meant to be on a wave 2 , In particular a drive or an output shaft, to be placed. The interior 3 can be positive or frictional with the shaft 2 get connected. Alternatively or additionally, the shaft attachment 1 also to another manner that seems appropriate to a professional with the wave 1 be connected. For example, the interior area 3 have axial recesses (not shown). The axial recesses may be formed as a form-locking element, the form-fitting elements, such as a feather key a positive connection with the shaft 2 received.

The outdoor area 5 is at least partially as an outer surface 11 educated. The outdoor area 5 also has at least one gear element 13 on that by the outside surface 11 and the forehead area 7 is limited. The gear element 13 is transverse, in particular orthogonal, to the axis a of the shaft attachment 1 arranged. Here is the gear element 13 as bevel gear element, in particular a bevel gear. Alternatively or additionally, the toothed element 13 at least partially parallel to the axis a of the shaft attachment 1 run. The gear element 13 is provided with a further gear element 13 , in particular another wave, positive and / or non-positive connected to transmit a movement, in particular a rotating movement, to another wave.

The inner surface 9 and the outer surface 11 form a thickness d, which is the thickness of the forehead area 7 of the wave tower. The thickness d is the difference between the outer diameter of the outer surface and the inner diameter of the inner surface.

The at least two forehead areas 7 limit the axial extent of the shaft attachment 1 , The at least one forehead area 7 has an axial elevation 15 with a support surface 17 on. The at least one forehead area 7 also has a to the support surface 17 , in particular axially, recessed end face 23 on. The support surface 17 the survey 15 closes transversely, in particular orthogonally, to the outside area 5 , preferably to the outer surface 11 , the wave tower 1 at. The support surface 17 , in particular annular support surface 17 , is provided in a jig, for example, from the mother 35 and one on the shaft 2 trained thread is to be clamped. The support surface 17 does not extend radially over the entire thickness d of the end portion 7 , The axial elevation 15 is in a radially outer region of the end region 7 arranged so that the radial extent of the survey 15 from the outside surface 5 of the outdoor area 11 radially to the inner surface 9 of the interior 3 up to 70%, in particular up to 65%, preferably up to 40%, preferably up to 20%, particularly preferably up to 10%. The face 23 is radial through the inner surface 9 of the interior 3 and the survey 15 , in particular the support surface 17 the survey 15 , limited. The assessment 15 may be formed through a bore, wherein the drill having a bore diameter smaller than a diameter of the outer surface 11 and larger than a diameter of the inner surface 9 , This can be a recess 21 be removed to the interior 9 followed.

3 shows a second embodiment of a wave attachment 1 , which is essentially similar to the first embodiment 2 in an angle grinder 100 or a cut-off grinder 100 out 1 is constructed. This embodiment differs only in the forehead area 7 from the first embodiment. The forehead area 7 The second embodiment has a survey 15 on, as a beveled or lowered end face 23 is trained. The bevelled or lowered end face 23 can be up to the outside area 5 , in particular to the outer surface 11 , extend. Here is the support surface 17 out 2 as, in particular annular, supporting contour 25 or as, in particular annular, supporting edge 25 formed, which is an axial extension of the shaft extension 1 limited and adapted to be clamped with a jig.

In 4 For example, a jig is shown that the shaft attachment 1 clamps. You can see a wave 2 , a ball bearing 33 , A mother 35 and a wave tower 1 , The wave 2 is rotationally formed about a rotation axis a. The wave 2 has a first section 37 on that into a second tapered section 39 passes. The rejuvenated second section 39 also indicates one of the first section 37 opposite end of a threaded area 41 on, which is intended with a mother 35 to form a high-strength connection.

At the second section 39 is the ball bearing 33 arranged. The ball bearing 33 is with an inner ring on the second section 39 the wave 2 arranged and axially through the first section 37 the wave 2 set. The ball bearing 33 is a known to a person skilled in ball bearings 33 that has an inner ring 43 , an outer ring 45 and having corresponding balls. This embodiment is not on a ball bearing 33 rather, a person skilled in the art can use any bearing he deems useful. The ball bearing 33 , especially the inner ring 43 of the ball bearing 33 , closes to a the first section 37 opposite second section 39 on the wave tower 1 , in particular at a first end area 7a of the wave tower 1 , at. The wave tower 1 is at a first forehead area 7a opposite second forehead area 7b axially with the nut 35 clamped.

The wave tower 1 is a wave attachment 1 according to the prior art to the forehead area 7 essentially analogous to the shaft attachments 2 and 3 educated. You can see an end face 23 of the first forehead area 7a , Alternatively or additionally, the second end area 7b also an end face 23 exhibit. The face 23 is curved and faces the inner ring 43 of the ball bearing 33 a point of contact which is approximately in the middle of the thickness d of the inner surface 9 of the interior 3 and the outer surface 11 of the outdoor area 5 acts. Such a curved face 23 may have been introduced by a hardening process due to production. This will over the face 23 reaches a support radius of the shaft attachment, which acts approximately in the middle of the thickness of the shaft attachment. This is not optimal, since with increasing support radius, an increase of the rigidity according to the invention can be introduced into the clamping device. This is achieved by the wave attachment according to the invention 1 according to one of the embodiments 2 or 3 ,

Claims (10)

Shaft attachment, in particular for a transmission, with an interior area ( 3 ) for putting on a shaft ( 2 ), the interior ( 3 ) opposite outdoor area ( 5 ) for function transfer and at least one forehead area ( 7 ) for the axial support of the shaft attachment ( 1 ), the shaft attachment ( 1 ) is formed as a hollow cylinder, characterized in that the at least one end region ( 7 ) an adjacent, in particular adjacent, to the outside area ( 5 ) at least partially axially projecting survey ( 15 ) having a support surface ( 17 ) for supporting the shaft attachment ( 1 ) forms on a counter body. Wave attachment according to claim 1, characterized in that the at least one end region ( 7 ) one to the outside area ( 5 ) subsequent support surface ( 17 ) and one to the interior ( 3 ) subsequent end face ( 23 ) having. Wave attachment according to claim 2, characterized in that the support surface ( 17 ) of the forehead area ( 7 ) as, in particular annular support surface ( 17 ) is trained. Wave attachment according to one of claims 2 to 3, characterized in that the end face ( 23 ) obliquely to the support surface ( 17 ) is arranged. Wave attachment according to one of the preceding claims, characterized in that the forehead area ( 7 ) from the interior ( 3 ) to the outdoor area ( 5 ) and in the axial direction of the forehead area ( 7 ) groundbreaking at least in sections steadily increasing, at least in sections increases arcuately or at least partially increases in steps. Shaft attachment according to one of claims 2 to 5, characterized in that the support surface ( 17 ) of the forehead area ( 7 ) as, in particular annular, supporting edge ( 25 ) is trained. Wave attachment according to one of the preceding claims, characterized in that the survey ( 15 ) has a radial extent of up to 70%, in particular up to 55%, preferably up to 40%, preferably up to 20%, particularly preferably up to 10%, of thickness (d). Wave attachment according to one of the preceding claims, characterized in that the outer region ( 5 ), in particular helical gear element ( 13 ) having. Wave attachment according to claim 8, characterized in that the gear element ( 13 ) is designed as a bevel gear. Hand tool with a wave attachment ( 1 ) according to any one of the preceding claims.

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