CN111033090B - Gear, apparatus for manufacturing gear, and method for manufacturing tooth portion of gear - Google Patents

Abstract

The invention relates to a gearwheel, to a device for producing a gearwheel and to a method for producing the toothing of a gearwheel, wherein the gearwheel has a flat toothing which covers a first radial distance region, in particular with respect to the central axis and/or the rotational axis of the gearwheel, is designed as a hub part and/or has a centrally arranged recess, in particular hollow, so that the gearwheel can be mounted on a shaft, covers a first axial region in the first radial distance region, covers a second axial region in the second radial distance region, which is radially spaced apart from the first radial distance region, is radially located within the first radial distance region, the second axial region comprising or at least overlapping the first axial region, and the gearwheel has, in the second radial distance region, in particular at the hub part neck of the gearwheel, a wall thickness and/or a radial thickness which decreases in the axial direction, in particular with increasing distance from the flat toothing, in particular smoothly and/or is connected to a slightly reducible wall thickness and/or a radial thickness as a function of the axial position.

Description

Gear, apparatus for manufacturing gear, and method for manufacturing tooth portion of gear

Technical Field

The present invention relates to a gear, an apparatus for manufacturing a gear and a method for manufacturing a tooth portion of a gear.

Background

It is generally known that a gear wheel formed with face teeth can be slipped onto a shaft and can be connected to the shaft in a rotationally fixed manner by means of a key connection.

In particular, a crown wheel is known from document DE 10 2005 024 455 A1.

To manufacture such crown gears, milling cutters are used, whose axial distance from the axis of rotation of the gear is greater than the internal diameter of the teeth of the gear and similar to those shown on the following internet web pages:

https://www.gloorag.ch/de/produkte/verzahnungswerkzeuge/ profilwalzfraser/vhm-profilwaelzfraeser.html，

https://www.gloorag.ch/de/produkte/verzahnungswerkzeuge/ kronradfraser/vhm-kronradfraeser.html。

a gear pair consisting of a crown gear and a pinion is known from DE 10 2004 062 379 B3.

A transmission assembly is known from DE 100 13 785 A1.

DE 43 09 559 A1 discloses an offset bevel gear.

A compact differential gear is known from DE 103 54 998 A1.

A milling method for bevel gears is known from CH 108 531A.

Disclosure of Invention

The aim of the invention is therefore to achieve as great a degree of freedom of linear movement as possible of the tool/tool.

An important feature of the invention is that the gear wheel has a flat toothing which covers a first radial distance region, in particular with reference to a central axis and/or a rotational axis of the gear wheel, wherein the gear wheel is embodied as a hub part and/or has a centrally arranged recess, in particular hollow, so that the gear wheel can be slipped onto the shaft, wherein the gear wheel covers a first axial region in the first radial distance region, wherein the gear wheel covers a second axial region in the second radial distance region, wherein the second radial distance region is radially spaced apart from the first radial distance region, wherein the second radial distance region is arranged radially inside the first radial distance region, wherein the second axial region comprises or at least overlaps the first axial region, wherein the gear wheel has in the second radial distance region, in particular at the hub part neck of the gear wheel, a wall thickness and/or a radial thickness which decreases in the axial direction, in particular as a function of the axial position, in particular smoothly and/or continuously differentiably.

The advantage here is that the tool can achieve as great a degree of freedom of linear movement as possible, since the tool can be guided up to the hub part neck of the gearwheel, in particular in the second radial distance region, and can therefore either be arranged in a manner movable in the direction of the axis of rotation of the tool or be designed very long. The concave, i.e. inwardly curved, embodiment of the hub part neck of the gear wheel allows for the most remote displacement of the tool or for the longest possible tool. Since the envelope surface of the tool is a cylinder, the outer edge of the cylinder locally contacts the hub part neck. The hub part shape thus has the largest hub part material with the optimum milling length and therefore results in a more stable gear body.

In an advantageous embodiment, the gear wheel covers a smaller axial region in a radial distance region arranged between the first radial distance region and the second radial distance region than in the first radial distance region and also than in the second radial distance region. The advantage here is that there is an undercut between the flat toothing and the second radial distance region.

In an advantageous embodiment, the reduced wall thickness or radial thickness is independent of the circumferential direction, with the exception of grooves, in particular keyways, which are arranged on the inner side of the gearwheel. It is advantageous here that the rotor region can be produced simply.

In an advantageous embodiment, the reduced wall thickness or radial thickness is implemented such that: the envelope surface of a tool, in particular a milling cutter, which produces a flat toothing, is brought into contact with the gear, in particular along the outer edge of the envelope surface. The advantage here is that a simple mathematical determination of the hub part neck and thus also a simple production is achieved.

In an advantageous embodiment, the axis of rotation of the tool has a non-zero axial distance from the central axis of the gear and/or the axis of rotation, and/or the axis of rotation of the tool is arranged parallel to the planar toothing and at a non-zero axial height above the planar toothing, in particular above the plane of engagement of the planar toothing with the tool. The advantage here is that the cutting tool projects laterally beyond the flat toothing and can therefore machine the entire width of the flat toothing even with a large axial distance, wherein for this purpose the cutting tool extends up to the hub part neck of the gear, the concave shape of which allows for a cutting tool that is as long as possible, i.e. long enough to machine the entire width of the flat toothing.

In an advantageous embodiment, the reduced wall thickness or radial thickness is implemented such that the circular outer edge of the envelope surface contacts the gear wheel, in particular independently of the rotational position of the gear wheel about its rotational axis and/or central axis, wherein the center of the circular outer edge has a distance, in particular an axial distance, which is not zero with respect to the rotational axis or central axis of the gear wheel, wherein the center of the circular outer edge has a distance, in particular an axial height, which is not zero with respect to the planar toothing, in particular with respect to the meshing region between the tool and the gear wheel, wherein the circular shape of the outer edge is arranged in the following planes: the normal direction of the plane is the axis of rotation of the tool or is oriented parallel to the axis of rotation of the tool. In this case, it is advantageous if only the outer edge of the envelope surface contacts and thus determines the shape of the hub part neck, i.e. the shape of the gear wheel in the second radial distance region. Therefore, simple manufacturing can be achieved.

In an advantageous embodiment, the radially outer surface of the gearwheel in the region of the second radial distance is identical to the region of the surface of the torus revolution body, which can be produced by rotating an arc region about the axis of rotation of the revolution body, wherein the axis of rotation is the central or rotational axis of the gearwheel. The advantage here is that, in a good approximation, a circular arc is sufficient as a shaping, and this circular arc then remains unchanged about the central axis of the gear, irrespective of the circumferential direction. Thus, a circular arc shaped region is a mathematical intersection between the gear and a plane containing the central or rotational axis of the gear. The intersection line is independent of the rotational position of the plane.

In an advantageous embodiment, the axial distance between the rotational axis of the tool and the rotational axis of the gearwheel is smaller than the inner radius of the toothing of the gearwheel, i.e. in particular is arranged at a smaller radial distance than the toothing of the gearwheel. The advantage here is that the outer edge of the end face of the envelope surface of the tool can move closer to the hub part neck during the milling of the gear teeth, i.e. almost touch. Thus, an optimal utilization of the cutting edges of the milling cutter can be achieved.

An important feature in the apparatus for manufacturing the teeth of the gear described above is that the tool is connected in a relatively non-rotatable manner to the shaft, wherein the tool is spaced apart from a point arranged on the axis of rotation of the shaft and having a minimum distance from the central or rotational axis of the gear, wherein the shaft contains the point. The advantage here is that the shaft can be supported on both sides of the gear and can therefore dissipate high transverse forces during production.

An important feature in the method for producing a toothed wheel toothing is that the toothed wheel is embodied as a hub part, in particular as a hollow hub part, having a hub part neck and a flat toothing, in particular wherein the hub part neck is radially spaced apart from the flat toothing, wherein the hub part neck tapers with increasing distance from the flat toothing, in particular with increasing distance from the flat toothing measured in the axial direction, wherein the flat toothing is produced with a working region, in particular a cutting region, of the tool, wherein an outer edge of the working region in the direction of the axis of rotation of the tool, in particular an outer edge in the direction of the axis of rotation of the tool, contacts, in particular linearly contacts, the hub part neck, in particular independently of the rotational position of the hub part neck about its axis of rotation and/or central axis, in particular wherein the outer edge is circular, wherein the center of gravity of the outer edge, in particular the center of the circle, has a non-zero spacing, in particular an axial spacing, from the rotational axis or the central axis of the toothed wheel, in particular wherein the spacing is smaller than the inner radius of the flat toothing, in particular is smaller than the smallest radial distance of the flat outer edge, in particular the center of the tooth, has a non-zero spacing, in relation to the axial spacing, in the axial distance, in the plane of the toothed part, in particular the axial distance, wherein: the normal direction of the plane is the axis of rotation of the tool and/or is oriented parallel to the axis of rotation of the tool.

The advantage here is that the cutting tool can be brought so close to the hub part neck that it contacts the hub part neck during the production of the flat toothing, for example by milling. Thus, the working area, i.e. the cutting area of the milling cutter, can be utilized as well as possible and a high service life can be achieved. The outer edge is the edge of the working area of the tool, viewed in the direction of the axis of rotation of the tool. When the tool is rotated, the outer edge is the end of the envelope surface of the working area of the rotating tool.

Here, contact is also understood to mean adherence to a safety distance, in particular, for example, less than 0.5 mm. When the safety distance is measured parallel to the axis of rotation of the tool, the safety distance is constant along the linear contact area. This therefore enables maximum use of the working face of the milling cutter. In the embodiment according to the invention, the hub part neck can be embodied very rigidly due to its shaping and the service life of the milling cutter is high.

An important feature in the method for producing a toothed wheel toothing is that the toothed wheel is embodied as a hub part, in particular as a hollow hub part, having a hub part neck and a flat toothing, in particular wherein the hub part neck is radially spaced apart from the flat toothing, wherein the hub part neck tapers with increasing distance from the flat toothing, in particular with increasing distance measured axially from the flat toothing, in such a way that: in particular, the circular outer edge of the envelope surface of a tool, in particular a milling tool, for producing a planar toothing is in contact, in particular in a linear manner, with the hub part neck, in particular independently of the rotational position of the hub part neck about its rotational axis and/or central axis, wherein the center of the circular outer edge has a non-zero distance, in particular an axial distance, relative to the rotational axis or central axis of the gearwheel, in particular wherein the distance is smaller than the inner radius of the planar toothing, in particular smaller than the minimum radial distance of the planar toothing, wherein the center of the circular outer edge has a non-zero distance, in particular an axial height, relative to the planar toothing, in particular relative to the region of engagement between the tool and the gearwheel, wherein the circular shape of the outer edge is arranged in the following plane: the normal direction of the plane is the axis of rotation of the tool or is oriented parallel to the axis of rotation of the tool.

The advantage here is that the cutting tool can be brought so close to the hub part neck that it contacts the hub part neck during the production of the flat toothing, for example by milling.

Here, contact is also understood to mean adherence to a safety distance, in particular, for example, less than 0.5 mm. When the safety distance is measured parallel to the axis of rotation of the tool, the safety distance is constant along the linear contact area. This therefore enables maximum use of the working face of the milling cutter. In an embodiment according to the invention, the hub part neck can be embodied very rigid and the service life of the milling cutter is high due to the shaping of the hub part neck.

Further advantages emerge from the dependent claims. The invention is not limited to the combination of features of the claims. Other possible combinations of the features of the claims and/or of the individual claims and/or of the features of the description and/or of the drawings may be made apparent to the person skilled in the art, in particular from the task set forth and/or by comparison with the prior art.

Drawings

The invention will now be explained in detail with the aid of the accompanying drawings:

fig. 1 schematically shows a gear wheel 5 together with a machining tool 1, wherein the envelope surface of the toothing of the gear wheel 5 and the tool 1 is shown instead of the toothing itself.

In fig. 2, the tool 1 is shown in engagement with the gear wheel 5, which is cut open so that the concave curvature of the hub part neck 3 of the gear wheel can be seen well.

In fig. 3, the tool 1 is shown in engagement with the gear wheel 5.

Detailed Description

As shown in the drawing, the tool, in particular the milling cutter, is connected to the shaft 2 in a rotationally fixed manner. The gear wheel 5 to be machined is embodied as a hub part and has a hub part neck 3 which narrows in the axial direction in its end region.

The gear wheel 5 has a flat toothing 4, which is radially spaced apart from the hub part neck 3. The planar toothing is preferably a helical planar toothing.

The envelope surface of the tool 1 is cylindrical. The imaginary axes of the tool 1 and the shaft 2 have an axial distance a with respect to the central axis of the gear wheel 5 and an axial height h with respect to the meshing plane of the planar toothing 4 of the gear wheel 5.

The tapering contour of the hub part neck 3 is a concave shape which is determined by the envelope surface of the tool 1.

The gear wheel 5 is hollow, so that the gear wheel 5 can be placed over a shaft and can be connected to the shaft in a rotationally fixed manner by means of a key connection. For this purpose, the gear wheel 5 has a keyway on the inner wall of the hub part neck 3, which keyway extends in the axial direction.

The planar toothing of the gearwheel 5 covers a first radial distance region. The gear wheel 5 covers a first axial region in this first radial distance region.

The region of the hub component neck is arranged with the inner wall in a second radial distance region, which is radially spaced apart from the first radial distance region and covers a second axial region in the axial direction, which includes the first axial region.

The gear wheel 5 has an axial narrowing in a radial distance region arranged between a first radial distance region and a second radial distance region. That is, in this narrowing the gear wheel 5 stretches axially less in the first radial distance region and in the second radial distance region.

The area of the flat toothing and the neck of the hub part projects axially beyond this narrowed area.

The envelope surface, i.e. the sheathing surface, of the tool 1 is the surface of the spatial area that is required and/or covered when the tool 1 is rotated about its axis of rotation.

The spatial region is a body of revolution, in particular a cylinder. The envelope surface is thus a corresponding cylindrical surface.

During the machining of the toothing, the tool 1 projects toward the hub part neck 3. The tapering shape of the hub part neck 3 is determined by the circular outer edge of the cylinder. In this case, the outer edge is forced to produce the contour of the hub part neck when it comes into contact with the hub part neck.

In this way, the tool 1 is allowed to approach the hub part neck as close as possible. A better utilization of the tool 1 is achieved with maximum retention of the material of the hub part.

The axis of rotation of the tool 1 is perpendicular to the axis of rotation 8.

The hub part neck 3 projects in the axial direction over the flat toothing 4. The hub part neck thus limits the linear degree of freedom of the tool 1, i.e. the movement of the tool 1 in the direction of its axis of rotation. For this purpose, the shape of the hub part neck 3 is determined by the envelope surface, in particular the circular outer edge of the envelope surface. Other parameters determining the shape of the hub member neck 3 are the axial spacing between the axis of rotation of the tool 1 and the axis of rotation of the gear 5, the axial height between the axis of rotation of the tool 1 and the plane of engagement, the length of the tool 1 and the envelope surface of the tool, i.e. the diameter of the cylinder.

In this way, the hub part neck is embodied in a concave shape. The wall thickness of the gear wheel 5, in particular of the hub part neck 3, tapers in the axial direction with increasing distance from the flat toothing 4. That is, the wall thickness of the hollow gear 5 decreases more and more in this direction with increasing distance from the flat teeth 4. In this case, the hub part shape always represents the maximum possible value of the hub part material in the respective optimum milling position.

The flat toothing 4 is preferably embodied as a helical flat toothing. The teeth of the planar toothing 4 extend in an arc shape, i.e. in the circumferential direction with increasing radial distance. The tool 1 is correspondingly designed as a pinion which cooperates with a helical flat toothing.

List of reference numerals:

1. tool, in particular milling cutter

2. Shaft

3. Neck of hub component

4. Plane tooth part

5. Gear wheel

Claims (11)

1. A kind of gear wheel is provided, which comprises a gear wheel,

wherein the gear has a planar toothing which covers a first radial distance region with reference to a central axis and/or a rotational axis of the gear,

wherein the gear is designed as a hub part and/or the gear has a centrally arranged recess, so that the gear can be slipped onto the first shaft,

wherein the gear covers a first axial region in a first radial distance region,

it is characterized in that the preparation method is characterized in that,

the gear covers the second axial region in a second radial distance region,

wherein the second radial distance zone is radially spaced from the first radial distance zone,

wherein the second radial distance zone is located radially inside the first radial distance zone,

wherein the second axial region comprises or at least overlaps the first axial region,

wherein the gear wheel, in the second radial distance region, at the hub part neck of the gear wheel, has a wall thickness and/or a radial thickness which decreases in the axial direction with increasing distance from the planar toothing, which wall thickness and/or radial thickness decreases smoothly and/or is slightly reducible as a function of the axial position, wherein the reduced wall thickness or radial thickness is designed such that, when the gear wheel is produced by means of the tool, the circular outer edge of the tool producing the planar toothing contacts the gear wheel,

wherein, the circle center of the circular outer edge has a non-zero axial line distance relative to the rotating axis or the central axis of the gear,

wherein the circle center of the circular outer edge has a non-zero axial height relative to the plane tooth part,

the circular shape of the outer edge is arranged in a plane, the normal direction of which is the rotational axis of the tool or is oriented parallel to the rotational axis of the tool.

2. Gear wheel according to claim 1, characterised in that the gear wheel covers in a radial distance zone arranged between the first radial distance zone and the second radial distance zone an axial zone which is smaller than in the first radial distance zone and than in the second radial distance zone.

3. Gear wheel according to any one of the preceding claims, characterised in that the reduced wall thickness or radial thickness is independent of the circumferential direction, except for the grooves arranged on the inner side of the gear wheel.

4. Gear wheel according to claim 1 or 2, characterised in that the reduced wall thickness or radial thickness is designed such that the envelope surface of the milling cutter producing the flat toothing contacts the gear wheel along the outer edge of the envelope surface.

5. Gear wheel according to claim 1 or 2, characterized in that the axis of rotation of the tool has a non-zero axial spacing with respect to the central axis and/or the axis of rotation of the gear wheel,

and/or

The axis of rotation of the tool is arranged parallel to the planar toothing and at an axial height above the planar toothing which is not zero.

6. Gear wheel according to claim 1 or 2, characterised in that the reduced wall thickness or radial thickness is designed such that, when the gear wheel is manufactured by means of the tool, the circular outer edge of the envelope surface of the milling cutter which manufactures the flat toothing contacts the gear wheel independently of the rotational position of the gear wheel about its rotational axis and/or central axis.

7. Gear wheel according to claim 1 or 2, characterised in that the radially outer surface of the gear wheel in the second radial distance region is equal to the region of the surface of the following rotation body: the rotary body can be produced by rotating a circular arc region about the axis of rotation of the rotary body, wherein the axis of rotation is the central or rotational axis of the gear.

8. A gear wheel according to claim 1 or 2, characterised in that the axial distance between the axis of rotation of the tool and the axis of rotation of the gear wheel is smaller than the inner radius of the teeth of the gear wheel, i.e. arranged at a smaller radial distance than the teeth of the gear wheel.

9. An apparatus for manufacturing a tooth section of a gear according to one of the preceding claims,

wherein the cutter is connected with the second shaft in a mode of relative rotation,

it is characterized in that the preparation method is characterized in that,

the tool is spaced from a point arranged on the axis of rotation of the shaft and having a minimum distance from the central or rotational axis of the gear,

wherein the axis includes the point.

10. A method for manufacturing a tooth section of a gear according to any one of claims 1 to 8,

it is characterized in that the preparation method is characterized in that,

the gear is designed as a hub component, which has a hub component neck and a planar toothing,

the hub member neck is radially spaced from the planar tooth portion,

wherein the neck of the hub part tapers with increasing distance from the planar toothing,

wherein the planar toothing is produced with the working area of the tool,

wherein an outer edge of the working area in the direction of the axis of rotation of the tool contacts the hub component neck,

wherein the outer edge is rounded,

wherein the center of gravity of the outer edge has a non-zero axial spacing with respect to the rotational axis or the central axis of the gear,

wherein the spacing is less than the inner radius of the planar tooth,

wherein the center of gravity of the outer edge has an axial height different from zero with respect to the planar tooth portion,

wherein the outer edge is arranged in a plane, the normal direction of which is the rotational axis of the tool and/or is oriented parallel to the rotational axis of the tool.

11. A method for manufacturing a tooth section of a gear according to any one of claims 1 to 8,

it is characterized in that the preparation method is characterized in that,

the gear is designed as a hub part having a hub part neck and a planar toothing,

wherein the hub component neck is radially spaced from the planar teeth,

wherein the hub part neck tapers with increasing distance from the planar toothing in such a way that:

so that the circular outer edge of the envelope surface of the milling cutter producing the flat toothing contacts the hub part neck,

wherein, the circle center of the circular outer edge has non-zero axial line distance relative to the rotating axis or the central axis of the gear,

wherein the spacing is smaller than the inner radius of the planar tooth portion,

wherein the circle center of the circular outer edge has a non-zero axial height relative to the plane tooth part,

the circular shape of the outer edge is arranged in a plane whose normal direction is the axis of rotation of the tool or is oriented parallel to the axis of rotation of the tool.

Images