DE102013206573A1 - stepper - Google Patents

Abstract

Step drill for machining a workpiece, in particular a metallic or mineral base, is provided, which contains a shaft element for holding the step drill in a holding device of a machine tool, for example a drilling machine, and a conical drilling head. In addition, the taper boring head contains a first taper drilling portion and a second taper drilling portion.

Description

INTRODUCTION

The present invention relates to a stepped drill for machining a workpiece, in particular a metallic or mineral substrate. The step drill contains a shaft element for holding the step drill in a holding device of a machine tool, for example a drill and a conical drill head. Stepped drills of the type described above are well known and are mainly used to create cylindrical holes in sheets, plates, profiles and pipes of steel, brass, copper, aluminum, V2A steels, mineral materials and various plastics. Here, the holes can be used, for example, a threaded bolt inserted through it and fixed by means of a lock nut in the workpiece. Another possibility is that a self-tapping screw is screwed into the through hole. Different material thicknesses are usually used for the two different types of attachment, since the screwing of a self-tapping screw requires a greater material thickness to ensure a sufficient carrying length of the thread. It is therefore appropriate to use for the drilling of the respective through hole step drills, which have different lengths drill stages. In the DE-Utility Model 20 2008 000 368 For example, such a step drill is disclosed in which a tapered cutting member is positioned on a cylindrically shaped clamping shaft. The conical cutting part is formed by a plurality of step-like mutually arranged cutting sections. At the front end of the conical cutting part, a twist drill is mounted as a drill bit. A disadvantage of the step drills of the prior art, however, is that no adjustment or no adaptation of the drilling stages can be made and thus often carried a variety of different step drills with correspondingly different drilling stages to the workplaces and attached to the machine tool for drilling different holes got to.

To solve the abovementioned disadvantages, a step drill according to the invention according to claim 1 is provided. Further advantageous embodiments of this step drill according to the invention are described in the dependent claims.

Accordingly, a step drill for machining a workpiece, in particular a metallic or mineral substrate is provided, which includes a shaft member for holding the step drill in a holding device of a machine tool, such as a drill, and a conical boring head. According to the invention, the conical boring head contains a first conical boring portion and a second conical boring portion.

According to an advantageous embodiment of the step drill according to the invention, a fixing device can be provided for fixing the first drilling portion relative to the second drilling portion, whereby the first drilling portion and the second drilling portion can be detachably connected to each other.

Moreover, it is possible according to a further advantageous embodiment, that the fixing device includes an axial insertion element having a first insertion end and a second insertion end, an axial receiving element having a first receiving end and a second receiving end and a holding device for receiving a holding element, wherein the holding device at least partially aligned perpendicular to the axial receiving element.

In order to prevent the first drilling portion from moving relative to the second drilling portion, it is further possible for the fixing apparatus to include a rotation lock.

According to a further advantageous embodiment of the present invention can be provided that the anti-rotation includes a polygonal Sicherungsseinsteckelement and a configured for receiving the Sicherungsseinsteckelements fuse receiving element. Due to the polygonal shape of the Sicherungsseinsteckelements and the corresponding fuse receiving element can effectively prevent the mutual rotation of these two elements to each other. The polygonal shape can be configured, for example, as a hexagon or in any other suitable form.

To ensure the largest possible contact surface between the fuse male and the fuse receiving element, according to a further advantageous embodiment of the inventive step drill be provided that the fuse male is positioned on the axial insertion element and the fuse receiving element on the axial receiving element.

In order to ensure that the first conical boring portion and the second conical boring portion are properly connected to one another, a position device with a position-inserting element and a position-receiving element can furthermore be provided on the stepped drill bit according to the invention.

In addition, the position male member may be positioned at the first insertion end of the axial insertion member and the position receiving member at the first receiving end of the position receiving member.

According to an advantageous embodiment of the step drill according to the invention, a helical drill point with a point angle between 103 ° and 133 ° can be provided, whereby an optimal drilling performance can be achieved.

Furthermore, it can further be provided that a drilling groove with an angle between 8 ° and 22 °.

The present invention will be explained with reference to advantageous embodiments, in this case shows

1 a side view of a step drill according to the invention comprising a conical boring head with a first conical bore portion and a second conical bore portion and a shaft member;

2 an isometric view of the step drill according to the invention;

3 a side view of the second Kegelbohranteils;

4 an isometric view of the anti-rotation device with a polygonal Sicherungsseinsteckelement and designed for receiving the Sicherungsseinsteckelements fuse receiving element and the positioning device with a Positionseinsteckelement and a position-receiving element; and

5 a sectional view through the first and second Kegelbohranteil with the anti-rotation device and the positioning device along the section line AA in 3 ,

Embodiment

1 and 2 shows the step drill according to the invention 1 for processing a workpiece (not shown), in particular a metallic or mineral substrate. Editing can be, for example, the chipping of a rock.

The step drill 1 contains a shaft element 10 and a conical boring head 20 ,

The shaft element 10 is in the form of a cylinder and serves to hold the step drill 1 in a (not shown) holding device of a machine tool, such as a drill. The holding device of the machine tool can be configured as a chuck. The cylindrical shape of the shaft element 10 may alternatively have a polygonal cross-section as an alternative to the round cross-section shown here.

The conical drill head 20 contains a first conical boring portion 30 , a second cone drilling portion 40 , a fixing device 50 and a central rotation axis R. A first bore groove 22 and a second drilling groove 24 are opposite each other on the outer surface of the conical boring head 20 arranged. The two drill grooves 22 . 24 thus run along the first Kegelbohranteil 30 and second cone drilling portion 40 , An optimal angle for the drill grooves 22 . 24 lies between 8 ° and 22 °.

The first cone drilling component 30 contains a first end 32 and a second end 34 and a variety of different drilling stages 35 , which are arranged stepwise in ascending form to each other. In addition, the first cone drilling portion contains 30 at the first end 32 a spiral drill bit 36 , The optimal point angle for the spiral drill bit 36 lies in a range between 103 ° and 133 °.

The second cone drilling component 40 contains a first end 42 and a second end 44 and a variety of different drilling stages 45 which are also arranged stepwise in ascending form to each other.

As in 1 and 4 shown, contains the fixing device 50 an axial insertion element 52 with a first introduction 52a and a second introductory one 52b and an axial receiving element 54 with a first recording end 54a and a second receiving end 54b ,

In addition, the fixing device contains 50 a holding device 60 for receiving a holding element 70 , The fixing device 50 serves to fix the first cone drilling portion 30 relative to the second cone boring portion 40 so that the two cone drill bits 30 . 40 are releasably secured together.

Furthermore, the fixing device contains 50 a rotation lock 55 , which in turn is a fuse plug 72 and a for receiving the fuse male element 72 designed fuse receiving element 74 having.

The fuse plug 72 is on the axial insertion 52 and the fuse receiving element 74 on the axial receiving element 54 positioned.

The fuse plug 72 on the axial insertion element 52 is formed in the shape of a hexagonal cylinder and contains a first insertion 72a as well as a second introductory one 72b , The first introductory 72a is at the second end 34 of the first cone drilling portion 30 positioned. Furthermore, the fuse male element 72 near the second introductory end 72b a recording area 80 for the holding element 70 on. The recording area 80 is formed in the form of a wedge-shaped recess. The interaction of the recording area 80 and the holding element 70 will be described in more detail below.

The fuse holder element 74 on the axial receiving element 54 is in the form of a hexagonal cylindrical bore in the second cone boring portion 40 formed along the axis of rotation R and corresponds in its cross section to the shape of the cross section of the Sicherungsseinsteckelements 72 , As a result, the fuse receiving element takes 74 the fuse male 72 rotatable in itself, which also makes the first cone drilling 30 non-rotatable to the second conical drilling portion 40 is held.

The holding device 60 is designed in the form of a cylindrical bore and extends perpendicular to the axis of rotation R of the outer surface of the second Kegelbohranteils 40 to the axial receiving element 54 in the second cone boring portion 40 , The cylindrical bore of the holding device 60 has a circular cross section. Alternatively, the cross section may have any other suitable shape. As in 5 shown is the retaining element 70 in the form of a cylindrical metal pin with a first holding element end 70a and a second retaining element end 70b educated. The cross section of the retaining element 70 is circular. Alternatively, however, the cross section may also have any other suitable shape. The cross-sectional shape of the holding element 70 should be the cross-sectional shape of the cylindrical bore of the holding device 60 correspond. The first holding element end 70a is formed in the form of a wedge. The wedge shape of the first end of the holding element 70a is designed to fit into the slot-shaped recess 80 of the axial insertion element 52 fits snugly.

Alternatively, according to further embodiments, the holding device 60 for receiving a holding element 70 be realized by a screw, in particular a grub screw, a pressure pin, an O-ring, a sheet metal clip or the like.

Furthermore, the fixing device contains 50 a positioning device 100 with a position male element 110 and a position-receiving element 120 , The positional insertion element 110 is at the first introductory 52a of the axial insertion element 52 positioned. As in 4 Shown is the cross section of the position male element 110 in the form of a circle with a segment of a circle cut off. The position-receiving element 110 again at the first end of recording 54a the axial receiving element 54 positioned. Like also in 4 shown is the cross section of the position-receiving element 120 in the form of a circle with a segment of a circle cut off. The cross-sectional shape of the position-receiving element 120 thus corresponds to the cross-sectional shape of the position male element 110 in that the positional insertion element 110 in the position-receiving element 120 can be included. The specific cross-sectional shape of the position male element 110 and the position-receiving element 120 allow it, that the axial insertion element 52 in only one orientation in the axial receiving element 54 can be fully introduced, reducing the first cone drill 30 Properly with the second cone drill 40 connected is.

Due to the design of the conical drilling head 20 with a first cone drilling portion 30 that of the second cone drill 40 can be solved, it is possible the first cone drill 30 to replace in a first embodiment by a tapered portion in another embodiment. The two embodiments of the first cone drill shares 30 may differ in particular in shape, height, diameter and number from each other. By attaching differently shaped conical boring portions, a first worn or worn conical boring portion can thus be obtained 30 be exchanged or a first tapered drill 30 with other, ie smaller or larger, drill stages are used.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 202008000368 [0001]

Claims (10)

Stepped drill bit ( 1 ) for machining a workpiece, in particular a metallic or mineral substrate, comprising - a shaft element ( 10 ) for holding the step drill ( 1 ) in a holding device of a machine tool, for example a drill; and - a (grooved) conical boring head ( 20 ), characterized in that the conical boring head ( 20 ) a first cone boring portion ( 30 ) and a second cone boring portion ( 40 ) contains. Stepped drill bit ( 1 ) according to claim 1, characterized in that a fixing device ( 50 ) for fixing the first cone drilling portion ( 30 ) relative to the second cone boring portion ( 40 ) is provided. Stepped drill bit ( 1 ) according to claim 2, characterized in that the fixing device ( 50 ) - an axial insertion element ( 52 ) with a first introductory 52a ) and a second introductory 52b ), - an axial receiving element ( 54 ) with a first receiving end ( 54a ) and a second recording end ( 54b ), and - a holding device ( 60 ) for receiving a retaining element ( 70 ), wherein the holding device ( 60 ) at least partially perpendicular to the axial receiving element ( 54 ) is aligned. Stepped drill bit ( 1 ) according to one of claims 1 to 3, characterized in that the fixing device ( 50 ) a rotation lock ( 55 ) contains. Stepped drill bit ( 1 ) according to claim 4, characterized in that the anti-rotation device ( 55 ) a polygonal fuse plug-in element ( 72 ) and a for receiving the fuse male element ( 72 ) configured fuse receiving element ( 74 ) contains. Stepped drill bit ( 1 ) according to claim 5, characterized in that the Sicherungsseinsteckelement ( 72 ) on the axial insertion element ( 52 ) and the fuse receiving element ( 74 ) on the axial receiving element ( 54 ) is positioned. Stepped drill bit ( 1 ) according to one of claims 1 to 6, characterized in that a position device ( 100 ) with a Positionseinsteckelement ( 110 ) and a position-receiving element ( 120 ) is provided. Stepped drill bit ( 1 ) according to claim 7, characterized in that the Positionseinsteckelement ( 110 ) at the first introductory 52a ) of the axial insertion element ( 52 ) and the position-receiving element ( 120 ) at the first receiving end ( 54a ) of the axial receiving element ( 54 ) is positioned. Stepped drill bit ( 1 ) according to one of claims 1 to 8, characterized in that a spiral drill bit ( 36 ) is provided with a tip angle between 103 ° and 133 °. Stepped drill bit ( 1 ) according to one of claims 1 to 9, characterized in that a drilling groove ( 22 . 24 ) is provided at an angle between 8 ° and 22 °.

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