阅读说明：本技术 例如钻头或铰刀的旋转切割工具 (Rotary cutting tool, such as a drill or reamer ) 是由 卢多维克·韦莫雷尔 蒂奥里·拉库图马拉拉-博纳富瓦 于 2020-03-25 设计创作，主要内容包括：本发明涉及一种旋转切割工具(1),例如钻头(2)或铰刀(3),其沿着轴线(4)纵向延伸并且包括至少一个主切割边缘(5),使得当工具(1)围绕轴线(4)旋转时,工具(1)轴向向前移动,以在材料上执行切割操作。根据本发明,工具(1)包括用于在切割操作期间制动工具(1)的轴向向前移动的制动装置(7)。(The invention relates to a rotary cutting tool (1), such as a drill (2) or a reamer (3), which extends longitudinally along an axis (4) and comprises at least one main cutting edge (5), such that when the tool (1) is rotated about the axis (4), the tool (1) is moved axially forward to perform a cutting operation on a material. According to the invention, the tool (1) comprises a braking device (7) for braking the axial forward movement of the tool (1) during the cutting operation.)

1. A rotary cutting tool (1), such as a drill (2) or a reamer (3), extending longitudinally along an axis (4) and comprising at least one main cutting edge (5), such that when the tool (1) is driven in rotation about the axis (4), the tool (1) is axially advanced to perform a cutting operation on a material, characterized in that it comprises means (7) for braking the axial advancement of the tool (1) during the cutting operation.

2. Tool (1) according to claim 1, characterized in that said braking means (7) are positioned axially set back with respect to said main cutting edge (5) and are intended to come into contact with the material being drilled during said drilling operation, in order to slow down said axial advancement of said tool (1).

3. Tool (1) according to claim 2, characterized in that the braking means (7) are in the form of an additional cutting edge (6) located downstream of the main cutting edge (5) with respect to the rotation of the tool (1) and having a lower cutting power than the main cutting edge (5).

4. Tool (1) according to claim 3, characterized in that the additional cutting edge (6) has a clearance angle (11) which is smaller than the clearance angle (12) of the main cutting edge (5).

5. Tool (1) according to one of the claims 3 or 4, characterized in that the additional cutting edge (6) has an axial cutting angle (9a) that is smaller than the axial cutting angle (10) of the main cutting edge (5).

6. Tool (1) according to claim 2, characterized in that the braking means (7) are in the form of a braking surface (8) positioned downstream of the main cutting edge (5) with respect to the rotation of the tool (1).

7. Tool (1) according to claim 2, characterized in that the braking means (7) are in the form of a braking edge (9) positioned downstream of the main cutting edge (5) with respect to the rotation of the tool (1).

8. Tool (1) according to claim 6, characterized in that the braking surface (8) is constituted by a secondary gap extending a primary gap (15) of the primary cutting edge (5), the angle (16) of the secondary gap being smaller than the angle (17) of the primary gap (15).

9. Tool (1) according to claim 2, characterized in that said braking means (7) are positioned axially set back by a distance comprised between 5 μm and 200 μm.

10. Tool (1) according to one of the preceding claims, characterized in that it is in the form of a drill bit (2), a reamer (3) with right-handed helix, a reamer, a sanding or chamfering tool.

11. Tool (1) according to one of the preceding claims, characterized in that it comprises a detent (7) on the tip or the entrance chamfer or, in the case of a stepped tool (1), on at least one step.

Technical Field

The present invention relates to the technical field of rotary cutting tools, such as screw tools, for drilling, boring, reaming, spot facing or chamfering operations by rotation.

The present invention relates in particular to drill bits, right-handed helical reamers, reaming bits, countersinks or chamfer milling cutters (milling cutters) and finds advantageous application in the field of aeronautics, where the assembly of an aircraft structure requires the drilling and reaming of a considerable number of holes in a part that may consist of a stack of layers, sometimes of different materials.

Background

Helical drilling tools, such as drill bits or right-handed helical reamers, comprising at least one main cutting edge and extending longitudinally along an axis are known in the art. These tools are intended to be rotated about an axis and axially advanced to perform a drilling operation on a material.

This type of tool may also be stepped or driven when large diameters need to be drilled in particularly hard materials such as steel or titanium, or when tight hole tolerances need to be achieved, or when guide holes are required for the assembly process of the parts to be drilled.

A problem with this type of rotary drill is the effect of the engagement of the tool with the material during drilling, which may be relatively high, which leads to a risk of the tool becoming clogged or broken.

This problem is exacerbated when the drilling operation is manual. In fact, it is difficult for the operator to control the feed of the tool into the material to be drilled and the tool must be held against the engagement force of the tool.

In addition, when the tool is stepped, there is also the problem of whipping of the impact material in the tool steps, which further increases the risk of jamming or breaking.

In order to avoid the risk of jamming or breaking, it is known to produce tools with inherently low joining forces in the material in this case by reducing the helix angle and/or by reducing the clearance angle of the cutting edge. This has the disadvantage of increasing the thrust force, which makes these manual operations time-consuming and tedious, with the result that the service life of the tool is reduced.

Disclosure of Invention

It is therefore an object of the present invention to remedy the above-mentioned drawbacks by providing a rotary cutting tool, for example helical, such as a drill, a reamer, a right-handed helical reamer, or having a cutting angle generated by a ramp, such as a sanding or chamfering tool, which avoids the risk of jamming or breaking during the cutting operation and in particular during manual drilling.

It is another object of the present invention to provide such a tool that allows for optimal drilling rates by reducing the cycle time of the drilling operation.

Another object of the invention is to provide such a tool which allows to reduce the thrust, increase the life of these tools and improve the drilling comfort and the hole quality.

To this end, a rotary cutting tool has been developed according to the prior art in that it extends longitudinally along an axis and has at least one main cutting edge, so that when the tool is rotated about the axis, the tool advances axially to perform a cutting operation on the material.

According to the invention, the tool comprises means for braking the axial advancement of the tool during the cutting operation.

The braking means included in the rotary tool thus make it possible to limit the effect of significant engagement of this type of tool in the material being drilled, enabling the user to better control the feed of said tool during manual drilling. As a result, the risk of jamming or breaking is avoided.

Furthermore, tool geometries with larger inherent engagement can be employed in conjunction with these braking devices, thereby reducing thrust and cycle time while avoiding the risk of jamming.

According to a particular embodiment, the braking means are positioned axially set back with respect to the main cutting edge and are intended to come into contact with the material to be drilled during the drilling operation, in order to slow down the axial advancement of the tool.

According to a particular embodiment, the braking means are in the form of an additional cutting edge, which is located downstream of the main cutting edge with respect to the rotation of the tool and has a lower cutting power than the main cutting edge.

For this purpose, the additional cutting edge has:

-an axial cutting angle smaller than the axial cutting angle of the main cutting edge;

and/or

-a clearance angle smaller than the clearance angle of the main cutting edge.

Other techniques are possible. For example, the additional cutting edge comprises an edge preparation, for example a so-called honing radius, i.e. the additional cutting edge is rounded and has a circular cross-section or facet.

In this way, the additional cutting edge has a lower cutting power than the main cutting edge, thus limiting the penetration of the additional cutting edge into the material, which makes it possible to control the feed of the tool when drilling manually or even when drilling automatically or semi-automatically with a column drill, a semi-automatic machine tool, an automatic drilling unit, or even under digital control.

The invention also allows the axial cutting angle and clearance angle of the main cutting edge to be increased, thereby increasing the cutting power and efficiency of the tool.

According to another particular embodiment, the braking means are in the form of a braking surface or edge positioned downstream of the main cutting edge with respect to the rotation of the tool.

The braking surface is formed, for example, by a secondary gap extending the main gap of the main cutting edge, the angle of the secondary gap being smaller than the angle of the main gap.

The braking edge is constituted, for example, by the trailing edge of the gap of the main cutting edge, which is set back from the main cutting edge and is not located in the generatrix of the gap.

According to a particular embodiment, the braking means are positioned axially set back from the main cutting edge by a distance comprised between 5 μm and 250 μm and preferably between 5 μm and 200 μm.

The rotary cutting tool according to the invention may be in the form of a drill, reamer, right-handed helical reamer, chisel or chamfer cutter and preferably comprises a detent on the tip or inlet chamfer or, in the case of a stepped tool, on at least one step so that the effects of jitter during manual drilling are eliminated.

Drawings

Further advantages and characteristics of the invention will become clearer from the following description, given by way of non-limiting example, from the accompanying drawings, in which:

FIG. 1 is a diagram illustrating a stepped or pilot drill bit according to the present invention;

FIG. 2 is a diagram illustrating a stepped or pilot right-handed helical reamer or reaming bit according to the present invention;

FIG. 3 is a diagram showing the main cutting edge and an additional cutting edge of the same drill bit, the additional cutting edge being axially set back and having a smaller axial cutting angle than the main cutting edge;

FIG. 4 is a diagram showing the main cutting edge and an additional cutting edge of the same drill bit, the additional cutting edge receding axially and having a smaller clearance angle than the main cutting edge;

FIG. 5 is a diagram showing the main cutting edge and an additional cutting edge of the same double flute drill bit, the additional cutting edge receding axially and having a smaller clearance angle than the main cutting edge;

FIG. 6 is a diagram showing the main cutting edge of a drill bit having a secondary clearance that extends the main clearance, the secondary clearance being at a smaller angle than the main clearance and being axially set back;

FIG. 7 is a diagram showing the trailing edge of the gap of the main cutting edge receding from the main cutting edge to form a braking edge;

FIG. 8 is a view of an additional cutting edge of a drill bit having a honing radius; and

FIG. 9 is a diagram illustrating additional cutting edges of a drill bit having facets.

Detailed Description

Referring to fig. 1 to 9, the present invention relates to a rotary tool (1) for performing a drilling or reaming operation, and particularly to a rotary cutting tool (1) such as a drill (2), a right-handed helical reamer (3), a sand mill or a chamfer mill, or the like.

In a known manner, and with reference to fig. 1 and 2, the tool (1) extends longitudinally along an axis (4) and has at least one main cutting edge (5), and preferably at least one additional cutting edge (6), which are opposite or not, so that when the tool (1) is rotated about the axis (4), the tool (1) advances axially to perform the actual drilling operation.

Depending on the application, in particular on the hardness of the material to be drilled, the drill (2) or reamer (3) may be stepped or guided and have a single or double flute, see fig. 5.

In fact, the tool (1) according to the invention finds advantageous application in particular in the field of aeronautics, where a relatively large number of holes must be drilled to assemble together parts, which sometimes require drilling of multilayer parts, possibly of different materials.

Thus, in order to facilitate the operation of drilling a hole of a relatively large diameter, the drill (2) or reamer (3) having a right-handed helix has several stages of sequentially increasing diameter.

In this application, right-handed helical drill bits (2) or reamers (3) are used in large numbers, and given the high torque and relatively large diameter required to drill hard materials such as steel or titanium, right-handed helical drill bits (2) or reamers (3) tend to have a very high engagement effect generated by the cutting angle or helically shaped slope of the tool (1).

This engagement effect is limiting when manual drilling is involved, since it is difficult for the operator to control the feed of the tool (1), which leads to a risk of breakage or jamming of the tool (1). Furthermore, these risks increase when the tool (1) is stepped, as the tool (1) is shaken at each step against the material being drilled.

The tool (1) according to the invention therefore comprises means (7) for braking the axial advancement of the tool (1) during the drilling operation.

To this end, according to a particular embodiment, the braking means (7) are positioned axially set back with respect to the main cutting edge (5) and are intended to come into contact with the material to be drilled during the drilling operation in order to slow down the axial advancement of the tool (1).

These braking means (7) may for example be in the form of an additional cutting edge (6), or in the form of a braking surface (8), or in the form of a braking edge (9).

With reference to fig. 3 to 5, 8 and 9, in the case of the additional cutting edge (6), which is located downstream of the main cutting edge (5) with respect to the rotation of the tool (1), and which has a lower cutting power than the main cutting edge (5) in order to contact the material being drilled and slow down the feed.

The fact that the additional cutting edge (6) has a lower cutting power limits the entry of said additional cutting edge (6) into the material, which makes it possible to control the feed rate in drilling, in particular in manual drilling.

In order to reduce the cutting power of the additional cutting edge (6), several techniques are possible.

For example, with reference to fig. 3, the additional cutting edge (6) has an axial cutting angle (9a) smaller than the axial cutting angle (10) of the main cutting edge (5). For example, for a drill bit having a main cutting edge (5) and a single opposite cutting edge, the axial cutting angle (10) of the main cutting edge (5) may be 30 °, while the axial cutting angle (9a) of the additional cutting edge (6) may be 20 ° or even negative.

According to another embodiment, and with reference to fig. 4 and 5, the additional cutting edge (6) has a clearance angle (11) which is smaller than the clearance angle (12) of the main cutting edge (5). As an example, the clearance angle (12) of the main cutting edge (5) is, for example, between 8 ° and 12 °, while the clearance angle (11) of the additional cutting edge (6) is, for example, 1 °.

Other ways of reducing the cutting power of the additional cutting edge (6) are to form a so-called honing radius (13) at the additional cutting edge (6) with a radius larger than 8 μm, for example 10 μm, see fig. 8, or to form a facet (14) or to chamfer the additional cutting edge (6), see fig. 9. The facet (14) may for example have a width of more than 10 μm. In the latter configuration, the result is similar to the arrangement of the additional cutting edge (6) with a smaller cutting angle and/or clearance than the main cutting edge (5), except for the reduction in size.

Referring to fig. 6, when the braking means is a braking surface (8), it is constituted, for example, by a secondary gap that extends the primary gap (15) of the primary cutting edge (5). The angle (16) of the secondary gap is smaller than the angle (17) of the primary gap (15) so that the braking surface (8) formed by the secondary gap comes into contact with the material to be drilled to slow down the advance of the tool (1). For example, the angle (17) of the main gap (15) is between 8 ° and 12 °, while the angle (16) of the auxiliary gap is 1 ° or even negative. In the case of a negative angle of the secondary gap, braking is achieved by a braking edge (9) constituted by the trailing edge of said secondary gap, see fig. 7.

With reference to fig. 7, when the braking means is a braking edge (9), it is in fact constituted by the trailing edge of the gap of the main cutting edge (5), which is set back with respect to the main cutting edge (5) and is not located in the generatrix of the gap.

The braking means (7) is preferably axially set back from the main cutting edge (5) by a distance of between 5 μm and 250 μm and preferably between 5 μm and 200 μm, depending on the spacing between the main cutting edge (5) and the braking means (7) in the rotational path (1) of the tool. For a drill bit having a main cutting edge (5) and a braking means (7) positioned on an opposite additional cutting edge (6), an axial distance of less than 5 μm will tend to prolong the cycle time of the tool (1) and shorten its life, while an axial distance of more than 250 μm will lead to the risk of jamming or breaking the tool (1) during the drilling operation.

The braking means (7) may be located directly on the tip of the drill bit, on the entry chamfer of the tool, or on one or more stages if necessary.

Another way of proposing the tool according to the invention is to consider that the braking means recede from the main cutting edge (5) and comprise a gap (11, 16) having a smaller angle, or even a negative angle, than the clearance angle (12, 17) of the main cutting edge (5) in order to create an edge which, depending on its position with respect to the groove, is cut or not cut, intended to come into contact with the material being drilled during the cutting operation, in order to slow down the axial advancement of the tool (1).

The geometry of the tool thus obtained has inherently contradictory properties, since the main edge helps the tool advance in the material with its axial cutting and clearance values, while the axial receding edge, generated by a clearance angle smaller than the main cutting edge, will limit the advance. The maximum feed rate of the tool (1) will be determined by the angle and axial position (i.e. helical offset) at which the edge is in contact with the material.

According to one embodiment, the gap for generating an axially receding edge intended to come into contact with the material to be drilled during the cutting operation to slow down the axial advancement of the tool is a gap (11) of an additional cutting edge (6) located downstream of the main cutting edge (5) with respect to the rotation of the tool (1) and having a lower cutting power than the main cutting edge (5).

According to another example, the gap that allows the generation of an axially receding edge and is intended to come into contact with the material being drilled during the cutting operation in order to slow down the axial advancement of the tool is a secondary gap (16) in the extension of the primary gap (15) of the primary cutting edge (5), so as to constitute a braking surface (8) positioned downstream of the primary cutting edge (5) with respect to the rotation of the tool (1) in the case where the angle of the secondary gap (16) is smaller than the angle (17) of the primary gap (15) and is negative, or a braking edge (9) constituted by the trailing edge of said secondary gap (16) in the case where the angle of the secondary gap (16) is smaller than the angle (17) of the primary gap (15) and is negative.

From the above it is clear that the present invention provides a rotary cutting tool (1) wherein the risk of jamming or breaking during drilling and in particular during manual drilling is avoided, while allowing an optimal drilling rate by reducing the cycle time of the drilling operation, and allowing reduced thrust, increased lifetime of these tools, and improved drilling comfort and hole quality.