IT201900005886A1 - TOOL FOR BEVELING A RAW TOOTHED WHEEL AND RELATIVE BEVELING METHOD - Google Patents

Description

DESCRIPTION

of the patent for industrial invention entitled:

"TOOL FOR BEVELING A RAW TOOTHED WHEEL AND RELATIVE BEVELING METHOD"

TECHNIQUE SECTOR

The present invention relates to a tool for chamfering a rough toothed wheel and a relative chamfering method.

ANTERIOR ART

Tools are known for chamfering edges comprised between a front surface and the sides of each tooth of the rough toothed wheel. In particular, the chamfering is carried out downstream of the roughing process, in which the rough toothed wheel is made with the help of a hob. Therefore, the bevel removes the sharp edges of each tooth to prevent the rough toothed wheel from being damaged or from damaging another toothed wheel with which it meshes during use. Furthermore, by removing the cutting edges, an operator is prevented from being injured during manipulation, for example assembly, of the gear wheel.

The tool for chamfering generally includes a plurality of tooth-shaped cutting elements, in which the cutting profiles are made on their own external lateral sides. In particular, the cutting elements have a shape which is substantially complementary to the shape of the space comprised between the two teeth of the rough toothed wheel.

During the chamfering process, both the tool and the rough toothed wheel are set in rotation. In particular, the tool is configured to rotate around a skewed axis with respect to the axis of the rough toothed wheel.

During the use of the known types of chamfering tools, each cutting element passes inside a respective space of the rough toothed wheel and bevels, by means of the cutting profiles on the external side flanks, two flanks facing each other by two teeth adjacent, which laterally delimit a respective space of the rough toothed wheel.

Therefore, substantially, a known type chamfering tool simultaneously chamfers the left side of the previous tooth and the right side of the next tooth which are engaged, during the reciprocal rotation, with the chamfering tool.

It is evident that a displacement of the tool for the chamfering with respect to the rough toothed wheel results in a non-symmetrical chamfering, i.e. one of the two sides is beveled more than the other. This is absolutely not welcome and therefore should be avoided, because it compromises the function of the bevel and subsequent correct meshing of the toothed wheel with another toothed wheel.

Known types of chamfering tools work substantially by plastic deformation of the flanks of two adjacent teeth, creating a tracing of the material, which compromises the finishing operations subsequent to finishing.

DESCRIPTION OF THE INVENTION

The purpose of the present invention is, therefore, to provide a tool for the chamfering of a rough toothed wheel and the relative chamfering method that are free from the drawbacks of the state of the art and that are easy and economical to make.

According to the present invention, a tool is provided for the chamfering of a rough toothed wheel according to what is mentioned in the attached claims.

According to the present invention, a beveling method is provided as claimed in the attached claims.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the invention, an embodiment is described purely by way of non-limiting example where:

Figure 1 is a schematic and perspective view of a tool for chamfering according to the present invention in an operative configuration;

Figure 2 illustrates a detail of Figure 1 in a first processing stage;

- figure 3 is similar to figure 2 and illustrates the same detail in a second processing stage;

- Figure 4 is a schematic view, with some parts removed for clarity of a tool according to the present invention during use; And

Figures 5 to 8 illustrate respective different types of bevels which can be made with the method according to the present invention.

PREFERRED FORMS OF IMPLEMENTATION OF THE INVENTION

In Figure 1, the number 1 generally indicates a tool for chamfering a rough toothed wheel 6 as a whole.

As illustrated in Figure 1, the rough toothed wheel 6 is a cylindrical element having a rotation axis Y and a thickness s. The rough toothed wheel 6 is axially delimited by two surfaces substantially perpendicular to said axis Y and hereinafter referred to as the front surface 3A and, respectively, the front surface 3B. The front surfaces 3A and 3B are opposite to each other.

Furthermore, the rough toothed wheel 6 comprises a plurality of teeth 5 which protrude radially outside the raw toothed wheel 6. Teeth 5 are evenly spaced.

Each tooth 5 has a 4 * right flank and a 4 ** left flank. Below the terms right and left are used with reference to the direction of rotation of the rough toothed wheel 6 during use. Flanks 4 * and 4 ** extend along the thickness s of tooth 5. The term flank 4 * or 4 ** means the entire lateral surface of tooth 5, i.e. the lateral surface extending between the circumference of head dt and the foot circumference dp of the rough toothed wheel 6. The head circumference dt is, in a known way, the circumference that externally limits the tooth 5 and the foot circumference dp is, in a known way, the internal circumference that internally limits the tooth 5. The terms internal and external are used with reference to the Y axis of rotation of the rough toothed wheel 6.

In particular, the rough toothed wheel 6 has an edge 2A between the front surface 3A and the sides 4 * and 4 **. Similarly, the rough toothed wheel 6 has an edge 2B between the front surface 3B and the sides 4 * and As will be better illustrated below, the tool 1 for chamfering is configured to chamfer each edge 2A, 2B. In other words, the tool 1 is configured to remove material along each edge 2A, 2B in order to create a chamfer 20A and, respectively, 20B (Figure 3). According to what is illustrated in Figures 5 to 8, the chamfer 20A can be continuous, or the entire edge 2A is blunt, or intermittent, or some portions of the edge 2A are not removed.

The tool 1 comprises a cylindrical body 7 having a rotation axis X and a substantially cylindrical lateral surface 8.

The tool 1 comprises a plurality of cutting elements 9 each of which protrudes radially from the lateral surface 8.

Each cutting element 9 has a right profile 10 and a left cutting profile 11, which laterally delimit a groove 12. Similarly to what was said previously, the terms right and left are used with reference to the direction of rotation of the tool 1.

As illustrated in greater detail in Figure 4, the groove 12 is configured to house, in use, a respective tooth 5 of the rough toothed wheel 6. The right profile 10 is configured to bevel, in use, the left 4 ** flank of a respective tooth 5. The left profile 11 is configured to bevel, in use, the right 4 * flank of a respective tooth 5.

In other words, each cutting element 9 simultaneously bevels both sides 4 * and 4 ** of the respective tooth 5.

Advantageously, the right profile 10 and the left profile 11 are different from each other. In other words, the profiles 10 and 11 do not have the same shape. Therefore the cutting element 9 is not made symmetrical along a transverse plane or perpendicular to the X axis of rotation.

According to a variant, the profiles 10 and 11 can be mirrored to each other.

The groove 12 has a profile made, in particular calculated, to cut an involute profile of a circle. In other words, the profiles 10 and 11 which laterally delimit the groove 12 are profiles made to cut the circle involute profile of the tooth 5.

Advantageously, each cutting element 9 projects helically around the lateral surface 8. In other words, each cutting element 9 is arranged along an imaginary helix which extends around the lateral surface 8 of the cylindrical body 7, so as to allow, in a known way, the meshing between the tool 1 and the rough toothed wheel 6 during use. In particular, the tool 1 for chamfering has a plurality of cutting elements 9 which protrude radially from the same axial portion pa of the tool 1 itself. In this case, it is said that the tool 1 has a plurality of threads / principles.

Advantageously, each cutting element 9 of an axial portion pa lies on a respective principle.

In use, as shown in Figure 1, the rotation X axis and the rotation Y axis are arranged substantially skewed to each other and the tool 1 rotates around the rotation axis X and the toothed wheel 6 respectively. rough around the Y axis of rotation.

Then the tool 1 approaches the rough toothed wheel 6. Advantageously, the tool 1 is synchronized with the rough toothed wheel 6 to make them mesh with each other without collisions.

Advantageously, the tool 1 and the rough toothed wheel 6 are synchronized with each other, so that a tooth 5 of the raw toothed wheel 6 is made to slide through a groove 12 of a respective cutting element 9.

In this way, the chamfering of at least a part of the edge 2A between the front surface 3A and the sides 4 * and 4 ** of the respective tooth 5 of the rough toothed wheel 6 is obtained by means of the cutting element 9.

The chamfering of the corner 2A can take place by means of one or more passes, or more passages of a tooth 5 through the respective groove 12. In the case of realization with several passes between one pass and the next pass, there is the further step of advancing the tool 1 radially towards the rough toothed wheel 6.

The geometry 20A, 20B of the final chamfer depends both on the shape of the profiles 10 and 11 of each cutting element 9 and on the reciprocal movements between the tool 1 and the rough toothed wheel 6 during machining. Figures 5 to 8 illustrate examples of different types of bevels 20 achievable with the tool 1 and the method according to the present invention.

Once the bevel of edge 2A has been completed, it is possible to proceed with the bevel of the other edge 2B, that is, of the edge 2B between the front surface 3B and the sides 4 * and 4 **. To bevel edge 2B it is first necessary to reverse the mounting direction of the tool 1 itself, disassembling it and reassembling it with the opposite direction to the previous one, so as to ensure that the right profile 10 and the left profile 11 face the edge 2B to be cut. . Subsequently, the tool 1 is moved axially along the X axis, so as to place each cutting element 9 in contact with the respective edge 2B. Furthermore, the direction of rotation of the tool 1 is reversed, so as to smooth the edge 2B between the front surface 3B, opposite to the front surface 3A, and the side 4 * and the side 4 ** of the respective tooth 5 of the rough toothed wheel 6.

Alternatively, to chamfer the edge 2B, it is possible to mount two tools 1 side by side, which have an inverted mounting direction with respect to each other, in such a way as to provide for the chamfering of the edge 2B without requiring any disassembly and reassembly of the tool. 1.

The tool 1 and the method described up to now have a plurality of advantages.

During the chamfering, a cutting process is carried out with tool 1. The bevel thus created has a better precision, a higher quality and avoids the tracing of the material, with consequent plastic deformation.

The groove 12 of the cutting elements 6 is substantially complementary to the shape of the tooth 5 of the rough toothed wheel 6. Therefore, it is ensured that the entire edge 2A or 2B of tooth 5 is chamfered.

Thanks to the tool 1 it is possible to obtain a plurality of different types of bevels 20. For example, it is possible to create: 20 constant bevels that affect the entire edge 2A or 2B (Figures 1 and 5); constant chamfers that only affect part of the corner 2A or 2B (figures 6 and 8); and comma bevels, that is to say bevels that have a beveled surface decreasing from the head towards the foot of tooth 5 (figure 7).

Claims (9)

CLAIMS 1. Tool (1) for the chamfering of a corner (2A; 2B) that extends between a surface (3A; 3B) and the sides (4 *, 4 **) of teeth (5) of a wheel (6 ) rough toothed and comprising: a cylindrical body (7) having a rotation axis (X) and a substantially cylindrical lateral surface (8); the tool (1) comprising a plurality of cutting elements (9), each of which protrudes radially from said lateral surface (8); the tool (1) is characterized in that each cutting element (9) has a first cutting profile (10) and a second cutting profile (11) which laterally delimit a groove (12), which is configured for housing, in use, a respective tooth (5) of the rough toothed wheel (6); said first cutting profile (10) and said second cutting profile (11) being configured to bevel at least part of said edge (2A, 2B). Tool (1) according to claim 1, wherein the first cutting profile (10) and the second cutting profile (11) are different from each other. Tool (1) according to claim 1 or 2, wherein the cutting profiles (10, 11) which laterally delimit the groove (12) are profiles made to cut an involute profile of a circle. Tool (1) according to any one of claims 1 to 3, wherein each cutting element (9) projects from said lateral surface (8) and extends along a respective helix profile. 5. Tool (1) according to claim 4, and comprising a plurality of cutting elements (9) in correspondence with the same axial portion of said tool (1); wherein each cutting element (9) extends along a respective thread. 6. Method for chamfering the flanks (4 *, 4 **) of teeth (5) of a rough toothed wheel (6) using a tool (1) for chamfering the flanks (4 *, 4 **) of teeth (5) and comprising a cylindrical body (7) having a first axis (X) of rotation and a substantially cylindrical lateral surface (8); the tool (1) comprising a plurality of cutting elements (9) each of which protrudes radially from said lateral surface (8); each cutting element (9) has a first cutting profile (10) and a second cutting profile (11) which laterally delimit a groove (12), which is configured to house a respective tooth (5) of the wheel (6 ) rough toothed; wherein the rough toothed wheel (6) comprises a second axis (Y) of rotation and a plurality of teeth (5), each tooth (5) being laterally delimited by a first flank (4 *) and a second flank (4 **); the method including the steps of: rotating said tool (1) for the chamfering around the first rotation axis (X); rotating the rough toothed wheel (6) to be chamfered around the second rotation axis (Y); wherein the second rotation axis (Y) is skewed with respect to the first rotation axis (X); bring the tool (1) for chamfering the sides (4 *, 4 **) close to the rough toothed wheel (6); synchronize the tool (1) for the chamfering with the rough toothed wheel (6), in such a way as to make them mesh with each other without collisions; in particular, by placing a tooth (5) of the rough toothed wheel (6) inside a groove (12) of a respective cutting element (9); And chamfer by means of each cutting element (9) at least part of a respective first edge (2A), which extends between a first front surface (3A), the first side (4 *) and the second side (4 **) of a respective tooth (5) of the rough toothed wheel (6). 7. Method according to claim 6, comprising the step of reversing the direction of assembly of the tool (1) and reversing the direction of rotation of the tool, so as to also bevel an edge (2B) between a second surface (3B) front, opposite to the first front surface (3A), and the first side (4 *) and the second side (4 **) of the respective tooth (5) of the rough toothed wheel (6). Method according to claim 6 or 7, wherein the bevel is performed with a single pass. Method according to claim 8, in which the chamfering is carried out with several passes, in which between a previous pass and the next pass there is the further step of advancing the tool (1) radially towards the toothed wheel (6) raw.