DE102005051174B4 - Tool and method for creating or finishing a thread - Google Patents

Abstract

The invention relates to a tool, in particular with a circular thread forming work area, for producing or reworking a thread, wherein a) the tool can be rotated about its tool axis, b) comprises at least two press studs projecting or projecting radially outward from the tool axis, c) each of which Press studs c1) each have a first foot region and a second foot region in the axial direction leading away from the shank, between which a vertex region is arranged, c2) the radial distance from the tool axis increasing in each case from the foot regions to the vertex region, d) a second Press studs in the tool circumferential direction or in the direction of rotation around the tool axis is arranged after a first press stud and e) the first foot region of the first press stud is offset in an axial direction from the first foot region of the second press stud and / or the second foot region of the first press stud is connected to the z wide foot region of the second press stud is offset in the same or in the opposite, axial direction with respect to the tool axis.

Description

The The invention relates to a tool and a method for producing or post-processing a thread.

to Threading or threading are next to machining Also known cutting methods and threading tools. Chipless process opposite cutting process has the advantage of high static and dynamic Strength even with larger thread depths because the material fibers are not cut. In addition fall no chips On, and the service lives are usually higher than with cutting taps.

An overview of in action there are threaded generating tools and working methods the Handbook of Threading and Milling Technology, published by: EMUGE-FRANKEN, Publisher: Publicis Corporate Publishing, year of publication: 2004 (ISBN 3-89578-232-7), hereinafter referred to as "EMUGE manual".

Under the non-cutting thread forming tools fall the so-called Thread former (see EMUGE Manual, chapter 9, pages 299 to 324) and, only for External thread, the thread rolling tools (see EMUGE manual, chapter 11, pages 373 to 404). Threaded rollers are working axially to their tool axis Threading tools with a trained on a tool shank Work area, which is a helical tool axis encircling effective area with which the thread upon rotation of the tool about the tool axis and axial feed along the tool axis is pressed into the workpiece.

Out WO 02/094491 A1 are a non-cutting working thread forming tool and a method for chipless threading known on a other, as a circular thread forms assignable working principle based. The thread forming tool disclosed in WO 02/094491 A1 is elongated and includes a work area with one or more annular grooves separated annular Comprehensive profiles (s). Each circumferential profile is non-circular in its center and has at least three elevations in the manner of a polygon as pressing lands on. additionally can also axially extending grooves between the individual pressure lugs on the outside surface of the Tool for feeding of cooling liquid be provided. As material for the tool is proposed either a carbide or high speed steel.

This Tool is now in the process according to WO 02/094491 A1 under rotation around its own axis into a hole with a larger diameter than the tool introduced and performs a circular one Movement along the circumference of the bore and at the same time a feed movement into the bore and thereby formed without cutting the thread in the bore.

The Thread is according to WO 02/094491 A1 so, in contrast to the axial thread furrows, not means a spiral, the thread pitch adapted effective area on the tool and a only axial or linear feed motion of the tool combined formed with a rotation about its own tool axis, but by means of annular and thus stepless and at the same time in cross-section polygonal active surfaces on Tool on the one hand and one with a rotation of the tool to its own longitudinal axis combined helical Movement of the tool resulting from a linear feed motion axially to the longitudinal axis of the tool and a circular movement of the longitudinal axis of the tool around a Center axis of the hole results, on the other hand.

This Thread former is also referred to below as a circular thread former or, under extension of the usual Nomenclature, as a circular thread furrow and the associated method referred to as circular thread forms or circular thread grooves.

Another circular thread former is also from the DE 103 18 203 A1 known. This known circular thread former has at least one, preferably at least two profile projections on its forming head, which are formed polygonal over the circumference and with circumferentially changing radial extent. The profile projections thereby form over the circumference in each case a plurality of pressing lugs, which may be evenly or unevenly distributed over the circumference. The pressing lugs of adjacent profile projections may also be offset from one another in the circumferential direction, in particular along a helix.

The Molded wedges or press studs in these known circular thread formers each have two Side areas (or: flank areas) and one furthest Outside protruding central area (or: apex area, head area). The radial distances the side areas of the tool axis of rotation take in the same Way to the central area towards, the pressure lugs are so with respect to a through the central region extending symmetry plane mirror symmetry built up.

In order to save time in the production of the thread, the forming head of the circular thread former, the circular thread forming work area, arranged with as many axially successively Driven cleats executed. In circular thread formers with many punching lugs, however, a relatively high friction occurs due to the large contact area to the workpiece. The high friction causes the tool life to be shortened.

The Variety of press studs leads on the other hand to do that on the workpiece via the press studs acting forces on a comparatively large area are distributed so that the acting on the surface to be machined Force per unit area is relatively low.

It is therefore an object of the invention, a new tool and a new Specify a method for producing a thread.

These The object is achieved by a tool having the features of the patent claim 1 and a method having the features of claim 25 solved. advantageous Embodiments and developments of the tool and the method according to the invention emerge from the claim 1 or claim 25th each dependent Claims.

• a) das Werkzeug um seine Werkzeugachse drehbar ist,
• b) wenigstens zwei von der Werkzeugachse radial nach außen vorstehende oder ragende Drückstollen umfasst,
• c) wobei jeder Drückstollen
• c1) jeweils in axialer, vom Schaft wegführender Richtung nacheinander einen ersten Fußbereich sowie einen zweiten Fußbereich aufweist, zwischen denen ein Scheitelbereich angeordnet ist,
• c2) wobei der radiale Abstand von der Werkzeugachse jeweils von den Fußbereichen zum Scheitelbereich hin zunimmt,
• d) ein zweiter Drückstollen in Werkzeugumfangsrichtung oder in Drehrichtung um die Werkzeugachse nach einem ersten Drückstollen angeordnet ist und
• e) der erste Fußbereich des ersten Drückstollens zu dem ersten Fußbereich des zweiten Drückstollens in einer axialen Richtung versetzt ist und/oder der zweite Fußbereich des ersten Drückstollens zu dem zwei ten Fußbereich des zweiten Drückstollens in derselben oder in der entgegengesetzten, bezüglich der Werkzeugachse axialen Richtung versetzt ist

According to claim 1, the invention comprises a tool, in particular with circular thread forming work area, for producing or post-processing a thread, wherein

• a) the tool is rotatable about its tool axis,
• b) comprises at least two press studs projecting radially outward from the tool axis or protruding,
• c) each pressing lug
• c1) has in each case in the axial direction, away from the shaft, a first foot area and a second foot area, between which a vertex area is arranged,
• c2) whereby the radial distance from the tool axis increases in each case from the foot regions to the vertex region,
• d) a second pressure lug in the tool circumferential direction or in the direction of rotation about the tool axis is arranged after a first press studs and
• e) the first foot region of the first press stud is offset from the first foot region of the second press stud in an axial direction and / or the second foot region of the first press stud is offset from the second foot section of the second press stud in the same or in the opposite axial direction with respect to the tool axis is offset

By the displacement of the foot areas the push lug reduces the simultaneously machined surface on the workpiece, so that the on the surface to be processed acting force per unit area without increase the overall friction increases which makes the tool easier to work without to shorten the service life of the tool.

Preferably are the pushers stepless arranged. This means in particular that curves, on the outside surface of the pressing lands run through points of equal distance from the tool axis, have no component in the direction of the tool axis. The tool can in this embodiment when machining or creating a thread in cheaper Rotate way around its axis. In pitchless arrangement of pressing lands elevated also the flexibility, the tool for use different thread diameter.

Prefers has at least one first pressure lug and at least one of the at least one first lug in the tool circumferential direction or in the direction of rotation of adjacent second press studs the same axial distance between the associated foot areas. At this embodiment are the foot areas the pressing lug in an axial direction offset from each other. It can be one alternating areal Machining of the thread through which the respective foot areas take place in the direction of the apex areas extending surfaces.

In a preferred embodiment the apex area of the first push lug points to the apex area a pressing lug adjacent in an axial direction at a greater distance as the apex region of one in the opposite axial direction adjacent tucking hole and / or the apex area of the first knocking lug is toward the apex area of the second push stud offset in the axial direction. This embodiment allows that the apex areas complement each other to work the threads.

Preferably is the axial distance from the first foot area to the apex area at the first press tunnel less than the distance from the second footer to the apex and / or the distance from the first foot area to the apex area second push lug greater than the distance from the second foot area to the vertex area. This embodiment allows that the foot areas complementary edit the threads.

Preferably, the tool has at least three in the tool circumferential direction or rotational direction successively arranged pressing lugs, wherein the apex region of each of these pressing lugs to the Vertex portions of the immediately adjacent in the tool circumferential direction or direction of rotation Drückstollen is offset by the same distance and / or wherein the or at least one of the first and the or at least one adjacent in an axial direction third pressure lugs are adjacent in each case axial directions Drückstollen, wherein the first pressing lugs have a distance to the immediately adjacent in the axial direction of the pressing lugs and a distance different from the distance in the opposite axial direction immediately adjacent press studs, and the third press studs the distance to the immediately adjacent in the axial direction of the press studs and the distance to Having in the opposite axial direction immediately adjacent press studs. In this embodiment, the offset staggered staggering rollers can be arranged alternately in the circumferential direction or rotational direction and / or in the axial direction. In this arrangement, the offset press studs extend over a large portion of the circular tap work area or over the entire circular tap area work area. As a result of the greater number of staggered pressure lugs, the workpiece can be processed even better without reducing the service life of the tool.

Preferably have at least one first punching lug and at least one second lug each a different axial distance between the associated foot areas on. The axial distance of the foot areas at least a first push-stud is bigger than the distance of the foot areas the at least one second Drückstollenens. This embodiment Relieves the pressure on the lug (s) with less axial distance the foot areas and concentrated thus its / their thread-producing or processing effect in the apex area.

In a preferred embodiment the apex area of the first push lug points to the apex area an adjacent in an axial direction Drückstollenens the same distance on as to the apex area of the in the opposite axial In the direction of the neighboring press tunnel and / or the vertex area of the first push stud to the apex area of the second push stud not offset in the axial direction. This embodiment reduces the radial Abdrängung of the tool or acting on the tool lateral forces.

Preferably is the distance from the first foot area to the vertex area equal to the distance from the second foot area to the apex area and the distance of the foot areas to the apex area of the first poking is bigger than the distance of the foot areas to the apex area of the second press stud. In this embodiment are mutually complementary foot areas in the formation of the threads educated. This embodiment is particularly advantageous in the final phase of machining the threads, in which the thread is already largely formed, and by the supplementary Training for the processing required high surface forces are applied more easily can.

Prefers the tool has at least three tool circumferential direction or in the direction of rotation successively arranged pressing lugs, wherein the differences the distances the foot areas at least a pushing lug and the distances of the footers the immediately adjacent in tool circumferential direction or direction of rotation pressing lands in amount each equal and greater than zero are. In this embodiment can the staggered arranged pressing lugs in the circumferential direction or rotation direction to be arranged alternately. hereby complete the effects of displacement during the rotation of the tool, In addition, the radial displacement of the tool decreases over a larger area of tool circumference or over the entire tool circumference.

Preferably the tool has at least three successive in the axial direction arranged press studs on, wherein at least one pressing lug the differences of the axial distance of the foot areas and the axial distance of the foot areas in the axial direction immediately adjacent press studs in terms of amount respectively are the same and different from zero. In this embodiment, the Staggered arranged thrust lugs in the axial direction be arranged alternately. This embodiment also reduces the radial displacement in the case of a plurality of thrust lugs arranged one after the other in the axial direction.

In an advantageous embodiment, a first, second, third and fourth pressure lugs are arranged one after the other in the circumferential direction or direction of rotation, the apex region of the first push lug is axially offset from the apex region of the second push lug and the apex region of the third push lug is not axially offset from the apex region of the fourth push lug , However, is arranged at different distances of the pressing lugs associated foot areas. In this embodiment can be arranged in the circumferential direction successively two offset to each other in the axial direction pressing lugs and adjacent to these two pressing lugs with different distances of the associated foot areas. This embodiment combines the benefits of complementary machining of the flanks of the the thread with the benefits of a smaller radial displacement of the tool.

• a) jeder Drückstollen
• a1) in Werkzeugumfangsrichtung oder Drehrichtung nacheinander wenigstens einen ersten Seitenbereich, einen Zentralbereich und einen zweiten Seitenbereich auf,
• a2) wobei der radiale Abstand jedes der Seitenbereiche von der Werkzeugachse jeweils zum Zentralbereich hin zunimmt,
• b) der Zentralbereich eines zweiten Drückstollens in Werkzeugumfangsrichtung oder Drehrichtung unter einem ersten Winkel in einem Drehsinn nach einem Zentralbereich eines ersten Drückstollens angeordnet ist,
• c) der Zentralbereich des ersten Drückstollens in Werkzeugumfangsrichtung oder Drehrichtung unter einem zweiten Winkel in dem Drehsinn nach einem Zentralbereich eines weiteren Drückstollens angeordnet ist und
• d) und der erste Winkel ungleich dem zweiten Winkel ist.

Preferably

• a) each push lug
• a1) in the tool circumferential direction or the direction of rotation one after the other at least a first side region, a central region and a second side region,
• a2) the radial distance of each of the side regions from the tool axis increasing toward the central region,
• b) the central region of a second pressing lug in the tool circumferential direction or the direction of rotation is arranged at a first angle in a direction of rotation after a central region of a first pressing lug,
• c) the central region of the first pressing lug in the tool circumferential direction or the direction of rotation is arranged at a second angle in the direction of rotation to a central region of a further pressing lug and
• d) and the first angle is not equal to the second angle.

It So there is a variable distribution of the pressing lugs or the central areas along the tool circumference. The variable allocation can, for example by different dimensions of the press studs in the tool circumferential direction or by different dimensions of the between the pressing lugs arranged spaces be achieved.

Especially preferred are in this embodiment several press studs arranged axially one after the other in rows, resulting in a variable pitch the rows results. The variable division results in improved Engagement conditions, such as less vibration.

• a) jeder Drückstollen
• a1) in Werkzeugumfangsrichtung oder Drehrichtung nacheinander wenigstens einen ersten Seitenbereich, einen Zentralbereich und einen zweiten Seitenbereich auf,
• a2) wobei der radiale Abstand jedes der Seitenbereiche von der Werkzeugachse jeweils zum Zentralbereich hin zunimmt,
• b) dem Zentralbereich eines ersten Drückstollens unter einem ersten Neigungswinkel zur Richtung der Werkzeugachse mit einer Komponente in Richtung der Werkzeugachse ein Zentralbereich eines dritten Drückstollens benachbart ist,
• c) dem Zentralbereich eines zweiten Drückstollens unter einem zweiten Neigungswinkel zur Richtung der Werkzeugachse mit einer Komponente in Richtung der Werkzeugachse ein Zentralbereich eines vierten Drückstollens benachbart ist,
• d) und der erste Neigungswinkel gleich oder ungleich dem zweiten Neigungswinkel ist.

In a further advantageous embodiment has

• a) each push lug
• a1) in the tool circumferential direction or the direction of rotation one after the other at least a first side region, a central region and a second side region,
• a2) the radial distance of each of the side regions from the tool axis increasing toward the central region,
• b) a central region of a third pressing lug is adjacent to the central region of a first pressing lug at a first angle of inclination to the direction of the tool axis with a component in the direction of the tool axis,
• c) adjacent to the central region of a second spinning lug at a second angle of inclination to the direction of the tool axis with a component in the direction of the tool axis is a central region of a fourth pressing lug,
• d) and the first inclination angle is equal to or different from the second inclination angle.

The Central areas can in this embodiment so helical be arranged offset. This results in a varying use Tooth feed, with constant center point feed and so a calmer Running through reduced vibrations.

Prefers are the pushers arranged axially one after the other in rows and between the rows Grooves and / or channels to the leadership a fluid medium, in particular a coolant and / or lubricant, arranged. An efficient supply of coolant is very advantageous for the Tool life, as overheating of the tool as well of the workpiece prevented or at least reduced.

Preferably is a carrier body, in particular a tool shank in which at least one pressing lug on a prefabricated Part is formed or formed from a prefabricated part and the or each prefabricated part on the carrier body by means of fastening means attached.

A Prefabrication reduces the cost of the production of the tool, also can be carrier body on the one hand and punching lugs on the other hand, from different and thus for the particular task manufacture well suited materials.

Especially It is advantageous if the tool shank consists of a tool steel, especially a high-speed steel is made. That can for example a high speed steel (HSS steel) or a cobalt alloy High speed steel (HSS-E-steel). The thread generation areas are generally made of a material that is harder than the material of the material Workpiece and sufficient toughness has, preferably made of hard metal or a hard metal alloy, in particular P-steel or K-steel or cermet, or of cemented carbide, in particular of tungsten carbide or titanium nitride or titanium carbide or titanium carbonitride or aluminum oxide or made of polycrystalline diamond (PCD).

Prefers the tool comprises a carrier body, in particular a tool shank in which at least one pressing lug is formed on the carrier body is, in particular by material removal such as grinding on the carrier body or Urformen generated together with the carrier body. this makes possible a particularly stable, in particular one-part embodiment, because no parts are fixed to each other.

In a preferred embodiment The tool has at least one additional cutting area additionally to the at least one pressing lug on. In this embodiment can in one operation both the cutting and the chipless Machining the workpiece done and thus the thread can be made very efficient.

• a) wenigstens ein zusätzlicher spanabhebender Bereich zum spanenden Erzeugen eines Vorgewindes in einer Werkstückoberfläche ausgebildet und vorgesehen und
• b) der wenigstens eine Drückstollen zum Fertigstellen des Gewindes durch Nachbearbeiten des Vorgewindes in der Werkstückoberfläche ausgebildet und vorgesehen.

Preferably, the tool is

• a) formed and provided at least one additional cutting area for machining a Vorgewindes in a workpiece surface and
• b) the at least one pressing lug for finishing the thread formed and provided by reworking the pre-thread in the workpiece surface.

These Combination allows a particularly fast and / or efficient production of a Vorgewindes and the completion of the thread in one operation.

In a preferred embodiment is that at least one extra cutting area a drilling area and / or a milling area. In this embodiment can in one operation both the making of the hole or of the milling area as well as the execution of the thread.

Preferably is at least a pressing tunnel for reworking and / or leveling of the threads or Thread flanks of the thread provided. With the help of this embodiment can advantageously irregularities of the thread are eliminated.

Prefers the tool has no cutting area and / or none Cut open. In this case, no chips fall during processing of the Thread on, so that the handling of the tool significantly simplified is.

Preferably is the first push tunnel from the second press tunnel spaced in the axial direction by 1 to 50% of the thread pitch.

In Trying has shown that this relative distance of the first pressing lobe from the second press tunnel particularly advantageous properties during processing or production of the thread.

In a concrete embodiment has been shown to be a spacing of the first lug from the second press tunnel in the axial direction by 3 to 20%, in particular 10%, particularly advantageous Features.

• a1) bei dem sich ein Werkzeug gemäß Anspruch 1 um seine Werkzeugachse dreht, und
• a2) sich mit einer linearen Vorschubbewegung entlang einer Vorschubrichtung parallel zur Werkzeugachse relativ zu einem Werkstück bewegt,
• a3) wobei das Werkzeug zusätzlich zu der linearen Vorschubbewegung eine Zirkularbewegung relativ zum Werkstück ausführt, bei der sich die Werkzeugachse um eine Mittelachse parallel zur Werkzeugachse bewegt,
• b) wobei das Werkzeug zur Erzeugung des Gewindes nacheinander den ersten Drückstollen in die Werkstückoberfläche und den zweiten Drückstollen eindrückt.

Moreover, according to claim 25, a method is proposed for producing or reworking a thread, in particular by circular thread forming,

• a1) in which a tool according to claim 1 rotates about its tool axis, and
• a2) moves with a linear feed movement along a feed direction parallel to the tool axis relative to a workpiece,
• a3) wherein, in addition to the linear feed motion, the tool performs a circular motion relative to the workpiece in which the tool axis moves about a central axis parallel to the tool axis,
• b) wherein the tool for generating the thread successively presses the first press studs in the workpiece surface and the second press studs.

Prefers indicates the first punching lug a first knitting profile and the second press stud one from the first press stud different second profile of action. Especially preferred, however independently claimed, supplement the effective profiles of the thread-processing press studs to the final profile.

In an advantageous embodiment is the action profile of the first pusher to the profile of action of the second press stud moved in the axial direction. This allows a particularly effective splitting the impact profile to the end profile.

Preferably has the profile of action of the first pusher in comparison to Action profile of the second push stud narrower distances the foot areas on. This reduces the radial displacement.

The The invention will be further explained below with reference to exemplary embodiments. there is also referred to the drawing, whose

1 the lateral surface of a tool with circular thread forming work area in plane projection,

2 the tool according to 1 in cross section,

3 the tool according to 1 in cross section,

4 the tool according to 1 in cross section,

5 another tool with circular thread forming work area in cross section,

6 another tool with circular thread forming workspace in perspective and

7 another tool with circular thread forming work area in cross section,
each in the inventive embodiment shows.

1 shows the lateral surface of a tool with circular thread forming work area with four rows 50 to 53 between each of which grooves 54 to 57 are arranged. Every row 50 to 53 each comprises six in the direction of the tool axis successively arranged pressing lugs 11 to 16 . 21 to 26 . 31 to 36 respectively 41 to 46 with vertex areas 11D to 16D . 21D to 26D . 31D to 36D respectively 41D to 46D , One another in the circumferential direction adjacent pressing lugs are each offset by the distance K in an axial direction. To the pressing lugs in the axial direction adjacent press studs, the difference in the absolute value of the distances is also K.

The press studs in 1 each have the same distance between their first foot areas 11E to 16E . 21E to 26E . 31E to 36E respectively 41E to 46E on the one hand and their second foot areas 11F to 16F . 21F to 26F . 31F to 36F respectively 41F to 46F on the other hand.

The pushers show at the in 1 shown projection of the lateral surface in cross-section substantially a square or approximately square shape. The next but two press studs 31 to 36 respectively 41 to 46 along the circumference are opposite the press studs 11 to 16 respectively 21 to 26 not offset in an axial direction, resulting in a total of a pitchless arrangement of the pressing lugs along the tool circumference.

When the tool rotates, first grabs the vertex area 11G in the thread to be generated, then engages the apex area 21G , then the vertex area 31G and finally the vertex area 41G forming into the thread to be produced. In this case, the offset in the axial direction staggered peaks 11G and 31G on the one hand and the vertex areas 21G and 41G on the other hand, complementary profiles of action to the final profile.

Upon further rotation of the tool, on the one hand, in particular, they grip from the apex areas 11G respectively. 31G towards the second foot areas 11F respectively. 31F extending areas, on the other hand, extending from the apex areas 21G respectively. 41G towards the first foot areas 21E respectively. 41E Forming areas forming in the thread to be generated and thus also form the end profile complementary active profiles.

The press studs 13 . 23 . 33 and 43 such as 15 . 25 . 35 and 45 behave accordingly. Also the press studs 22 . 32 . 42 and 12 such as 24 . 34 . 44 and 14 such as 26 . 36 . 46 and 16 behave analogously.

2 shows the tool according to 1 in cross section with four rows 50 to 53 between each of which grooves 54 to 57 are arranged. The shown press studs 11 . 21 . 31 such as 41 each have side panels 11A . 21A . 31A . 41A such as 11C . 21C . 31C . 41C and central areas 11B . 21B . 31B . 41B on. The radial distance of each of the side regions from the tool axis B increases toward the respective central region.

3 shows the tool according to 1 in another, orthogonal to the cross section in 2 arranged cross-section. 3 shows press studs 21 to 26 with vertex areas 21D to 26D as well as first foot areas 21E to 26E and second foot areas 21F to 26F ,

The press studs 22 . 24 and 26 are opposite to the circumferentially adjacent press studs 12 . 14 and 16 offset axially. The press studs 21 to 26 have distances relative to the respective adjacent in the axial direction pressing lugs, which differ in magnitude by the value K.

The Apex areas are each orthogonal to the central areas arranged.

The second foot areas 21F . 23F such as 25F the push lug 21 . 23 and 25 each have a greater distance from the respective vertex area 21G . 23G respectively. 25G on as the first foot areas 21E . 23E respectively. 25E the push lug 21 . 23 and 25 opposite the respective vertex areas 21G . 23G and 25 ,

The second foot areas 22F . 24F such as 26F the push lug 22 . 24 and 26 each have a smaller distance from the respective vertex area 22G . 24G respectively. 26G on as the first foot areas 22E . 24E respectively. 26E the push lug 22 . 24 and 26 opposite the respective vertex areas 22G . 24G and 26 ,

4 shows the tool according to 1 in another, orthogonal to the cross section in 2 arranged cross-section. 4 shows press studs 31 to 36 ,

The press studs 32 . 34 and 36 are opposite to the circumferentially adjacent press studs 22 . 24 and 26 offset axially. The press studs 31 to 36 have distances relative to the respective adjacent in the axial direction pressing lugs, which differ in magnitude by the value K.

5 shows another tool with circus largewindeformer workspace in cross section. The press studs 21 ' to 26 ' each have first foot areas 21E ' to 26E ' as well as second foot areas 21F ' to 26F ' with intervals 21G ' to 26G ' between them, the pushers 31 ' to 36 ' each have first foot areas 31E ' to 36E ' as well as second foot areas 31F ' to 36F ' with intervals 31G ' to 36G ' between them.

The distances 21G ' to 26G ' the push lug 21 ' to 26 ' are each less than the distances by the same amount 31G ' to 36G ' the circumferentially adjacent, recognizable in the background press studs 31 ' to 36 ' ,

The press studs have in the in the 3 to 5 shown, extending through the tool axis cross-sections substantially the shape of isosceles triangles, wherein the outwardly directed tip is rounded in each case.

6 shows another tool with circular thread forming workspace in perspective view. 6 shows press studs 61 to 70 with central areas 61B to 70B as well as page areas 61A to 70A respectively. 61C to 70C ,

The radial distance of each of the side areas 61A to 70A respectively. 61C to 70C from the tool axis B takes each to the respective central area 61B to 70B towards. The through the central areas 61B to 65B running first straight 80 forms an angle λ1 to the direction of the tool axis with a component in the direction of the tool axis passing through the central areas 66B to 70B running second straight line 81 forms an angle λ2 to Rich direction of the tool axis with a component in the direction of the tool axis. The angle λ2 is greater than the angle λ1.

7 shows another tool with circular thread forming work area in cross section. The rows 51 and 53 are opposite the ranks 50 and 52 offset by the angle Δ with respect to a 90 ° pitch. The rows 52 and 50 respectively 51 and 53 form a 180 ° angle to each other. Between the rows are grooves 54 to 57 arranged. The grooves 55 and 57 have a greater width than the grooves 54 and 56 on.

1

Circular thread former

2

shaft

11 to 16, 21 to 26, 31 to 36, 41 to 46, 21 to 26 ', 30' to 36 ', 61 to 70

pressing lands

13E, 23E, 33E, 43E, 21E 'bis 26E '

first footers

13F, 23F, 33F, 43F, 21F 'to 26F '

second footers

13D, 23D, 33D, 43D

apex regions

13G, 23G, 33G, 43G, 21G 'bis 26G '

Distances foot areas

50 to 53

string

54 to 57

groove

61A up to 70A, 61C to 70C

page sections

61B to 70B

Central areas

80

first Just

81

second Just

B

tool axis

K to M

Distances vertex areas

P to S

Distances footprints-apex areas

V to Z

Distances press studs

Claims (29)

Tool ( 1 ) for producing or reworking a thread, wherein a) the tool is rotatable about its tool axis (B), b) at least two pressing lugs projecting radially outward from the tool axis ( 23 . 33 ), c) each pushing lug c1) in each case in axial, by the shaft ( 2 ) leading away a first foot area ( 23E ) and a second footer ( 23F ) between which a vertex area ( 23D c2) wherein the radial distance from the tool axis (B) in each case from the foot areas ( 23E . 23F ) to the vertex area ( 23D ), d) a second pressure lug ( 33 ) in the tool circumferential direction or in the direction of rotation about the tool axis after a first pressing lug ( 23 ) and e) the first foot area ( 23E ) of the first pusher ( 23 ) to the first footer ( 33E ) of the second pusher ( 33 ) is offset in an axial direction and / or the second foot area ( 23E ) of the first pusher ( 23 ) to the second footer ( 33E ) of the second pusher ( 33 ) is offset in the same or in the opposite, with respect to the tool axis axial direction, f) wherein the pressing lugs are arranged steplessly. The tool of claim 1, wherein the tool comprises a Circular thread forming work area has. Tool according to claim 1 or 2, wherein at least one first press stud ( 23 ) and at least one of the at least one first press studs in the tool circumferential direction or in the direction of rotation of adjacent second press studs ( 33 ) the same axial distance ( 23G . 33G ) between the associated foot areas ( 23E . 23F ; 33E . 33F ) exhibit. Tool according to one of the preceding claims, wherein the vertex area ( 23D ) of the first pusher ( 23 ) to the vertex area ( 22D ) an adjacent in an axial direction Drückstollens ( 22 ) has a greater distance than the vertex area ( 24D ) of an adjacent in the opposite axial direction Stollen ( 24 ) and / or where the vertex area ( 23D ) of the first pusher ( 23 ) to the vertex area ( 33D ) of the second pusher ( 33 ) is offset in the axial direction. Tool according to one of the preceding claims, wherein the axial distance (P) from the first foot area ( 23E ) to the vertex area ( 23D ) at the first punching lug ( 23 ) smaller than the distance (Q) from the second foot area ( 23F ) to the vertex area ( 23D ) and / or wherein the distance (R) from the first foot area ( 33E ) to the vertex area ( 33D ) at the second pressure lug greater than the distance (S) from the second foot area ( 33F ) to the vertex area ( 33D ). Tool according to one of the preceding claims, comprising at least three in the tool circumferential direction or direction of rotation sequentially arranged spinning lugs ( 23 . 33 . 43 ), wherein the vertex area ( 33D ) each of these pushers ( 33 ) to the vertices ( 23D . 43D ) in the tool circumferential direction or direction directly adjacent press studs ( 23 . 43 ) is offset axially by the same distance (K) and / or wherein the or at least one of the first (23) and the or at least one adjacent third thrust lug (3) in an axial direction ( 24 ) in each case in both axial directions 22 . 24 ; 23 . 25 ) are adjacent, wherein the first pressure lug ( 23 ) a distance (V) to the immediately adjacent in the axial direction of the pressing lugs ( 24 ) and a distance (W) different from the distance (V) to the pressure lug (13) immediately adjacent in the opposite axial direction (FIG. 22 ), and the third pressure lug ( 24 ) the distance (W) to the immediately adjacent in the axial direction of the pressing lugs ( 25 ) and the distance (V) to the immediately adjacent in the opposite axial direction Stollen ( 23 ) having. Tool according to one of the preceding claims, wherein at least one first press stud ( 23 ' ) and at least one second pressure lug ( 33 ' ) each have a different axial distance between the associated foot areas. Tool according to one of the preceding claims, wherein the vertex area ( 23D ' ) of the first pusher ( 23 ' ) to the vertex area ( 24D ' ) an adjacent in an axial direction Drückstollens ( 24 ' ) is at the same distance as the vertex area ( 22D ' ) of the adjacent in the opposite axial direction Drückstollens ( 22 ' ) and / or where the vertex area ( 23D ' ) of the first pusher ( 23 ' ) to the vertex area ( 33D ' ) of the second pusher ( 33 ' ) is not offset in the axial direction. Tool according to one of the preceding claims, wherein the distance (P ') from the first foot area ( 23E ' ) to the vertex area ( 23D ' ) equals the distance (Q ') from the second foot area ( 23F ' ) to the vertex area ( 23D ' ) and wherein the distance (P ', Q') of the foot areas ( 23E ' . 23F ' ) to the vertex area ( 23D ' ) of the first pusher ( 23 ' ) greater than the distance (R ', S') of the foot areas ( 33E ' . 33F ' ) to the vertex area ( 33D ' ) of the second pusher ( 33 ' ). Tool according to one of the preceding claims, wherein the tool ( 1 ) at least three in the tool circumferential direction or in the direction of rotation successively arranged pressing lugs ( 23 ' . 33 ' . 43 ' ), wherein the differences of the distances of the foot areas ( 33E ' . 33F ' ) at least one pushing lug ( 33 ' ) and the distances of the foot areas ( 23E ' . 23F '; 43E ' . 43F ' ) in the tool circumferential direction or direction directly adjacent press studs ( 23 ' . 43 ' ) are each equal to and greater than zero in amount. Tool according to one of the preceding claims, wherein the tool ( 1 ) at least three in the axial direction successively arranged pressing lugs ( 22 ' . 23 ' . 24 ' ), wherein at least one pressure lug ( 23 ' ) the differences of the axial distance ( 23G ' ) of the foot areas ( 23E ' . 23F ' ) and the axial distance ( 22G ' . 24G ' ) of the foot areas ( 22E ' . 22F ' . 24E ' . 24F ' ) of the immediately adjacent thrust lugs ( 22 ' . 24 ' ) amount equal in each case and are different from zero. Tool according to one of the preceding claims, wherein a first ( 13 '' ), second ( 23 '' ), third ( 33 '' ) and fourth ( 43 '' ) Pressing lugs are arranged one after the other in the circumferential direction of the tool or the direction of rotation, the vertex area ( 13D '' ) of the first pusher ( 13 '' ) to the vertex area ( 23D '' ) of the second pusher ( 23 '' ) is offset axially and the apex area ( 33D '' ) of the third push stud ( 33 '' ) to the vertex area ( 43D '' ) of the fourth push stud ( 43 '' ) are not offset axially, but at different distances ( 33G '' . 43G '' ) of the footsteps associated footsteps ( 33E '' . 33F '' . 43E '' . 43F '' ) is arranged. Tool according to one of the preceding claims, a) wherein each pressing lug a1) in the tool circumferential direction or direction of rotation successively at least a first side region ( 60 ), a central area ( 62 ) and a second page area ( 61 a2) wherein the radial distance of each of the side regions from the tool axis (B) to the central region ( 63 ), b) the central area ( 64 ) of a second pressing lug in the tool circumferential direction or the direction of rotation at a first angle in a direction of rotation towards a central region ( 63 ) of a first pressing lug is arranged, c) the central region ( 63 ) of the first pressing lug in the tool circumferential direction or the direction of rotation at a second angle in the direction of rotation toward a central region ( 62 ) of a further pressing lug is arranged and d) and the first angle is not equal to the second angle. Tool according to one of claims 1 to 12, a) wherein each pressing lugs a1) in the tool circumferential direction or direction of rotation at least one first side region ( 60 ), a central area ( 62 ) and a second page area ( 61 a2) wherein the radial distance of each of the side regions from the tool axis (B) to the central region ( 63 ), b) the central area ( 63 ) of a first pressing lug at a first inclination angle to the direction of the tool axis (B) with a component in the direction of the tool axis, a central region ( 65 ) is adjacent to a third push stud, c) the central area ( 64 ) a second pressing lug at a second angle of inclination to the direction of the tool axis (B) with a component in the direction of the tool axis a central region ( 66 ) is adjacent to a fourth pressing lug, d) and the first inclination angle is equal to or different from the second inclination angle. Tool according to one of the preceding claims, wherein the pressure lugs axially successively in rows ( 50 . 51 . 52 . 53 ) and between the rows of grooves and / or channels ( 54 . 55 . 56 . 57 ) are arranged for guiding a fluid medium, in particular a coolant and / or lubricant. Tool according to one of the preceding claims, with a carrier body, in particular a tool shank ( 3 ), in which at least one pressing lug ( 13 . 23 . 33 . 43 , ...) is formed on a prefabricated part or is formed from a prefabricated part and the or each prefabricated part is fastened to the carrier body by means of fastening means. Tool according to one of the preceding claims with a carrier body, in particular a tool shank ( 3 ), in which at least one pressing lug ( 13 . 23 . 33 . 43 , ...) is formed on the carrier body, in particular by material removal such as grinding on the carrier body or prototypes is generated together with the carrier body. Tool according to one or more of the preceding claims, having at least one additional cutting area in addition to the at least one pressing lug ( 13 . 23 . 33 . 43 , ...). A tool as claimed in claim 18, wherein a) at least one additional cutting area is provided and provided for cutting a preliminary thread in a workpiece surface, and in which b) the at least one pressing lug ( 13 . 23 . 33 . 43 , ...) is designed and provided for finishing the thread by reworking the preliminary thread in the workpiece surface. Tool according to claim 18 or 19, wherein the at least an additional machining area is a drilling area and / or a milling area. Tool according to one of the preceding claims, wherein at least one pressing lug ( 13 . 23 . 33 . 43 , ...) is provided for reworking and / or leveling of the threads or thread flanks of the thread. Tool according to one of claims 1 to 17, which does not have a cutting Has area and / or no cutting edge. Tool according to one of the preceding claims, wherein the first pressure lug of the two th press studs in the axial direction by 1 to 50% of the thread pitch is spaced. Tool according to one of the preceding claims, wherein the first punching lug from the second press tunnel in the axial direction by 3 to 20%, in particular 10%, spaced is. Method for producing or postprocessing a Thread, by circular thread forming, a1) in which a Tool according to claim 1 rotates about its tool axis (B), and a2) with a linear feed motion along a feed direction parallel moved to the tool axis relative to a workpiece, a3) where the Additional tool to the linear feed motion a circular motion relative to workpiece executing, in which the tool axis about a central axis parallel to Tool axis moved, b) wherein the tool for generating the Thread one after the other the first press studs into the workpiece surface and press in the second press stud. The method of claim 25, wherein the first punching lug a first knitting profile and the second press stud one from the first press stud having different second profile of action. The method of claim 25 or 26, wherein the Impact profiles of the thread-processing press studs supplement the end profile. A method according to claim 25, 26 or 27, wherein said Action profile of the first push lug to the profile of action of the second press stud is shifted in the axial direction. The method of claim 25, 26, 27 or 28, wherein the action profile of the first pusher in comparison to the action profile of the second Drückstollens narrower distances of footers having.