DE202007019480U1 - Pull-out protection of tools from tool holders with a tool holder - Google Patents

Abstract

System of tool holder and tool, wherein the tool holder has a cylindrical tool holder, preferably a chuck, and the cylindrical shaft of the tool, in particular a rotary tool, is received therein, wherein the system has a pull-out safety device which blocks axial migration of the tool, which at least one blocking element and at least one corresponding to this and the locking element receiving locking groove, which interact positively, wherein the locking groove is arranged in the circumferential surface of the shaft of the tool and the locking element in the chuck or vice versa, characterized in that the locking groove course is helical, L-shaped, curved or composed of sections straight and / or curved cylinder surface paths is formed.

Description

The present invention relates to tool holders with a tool holder, in particular shrink chucks and other chucks for receiving rotary tools according to the preamble of claim 1.

Tool holders with chucks, in particular shrink chucks are widely known. They are used for clamping pipe, turning, milling, grinding and grinding tools o. The like. Via a thermally induced shrinkage process. Usually, such shrinkage chucks are thermally heated by an inductive shrinking system, whereby the inner diameter of the shrink chuck increases. With an enlarged inner diameter, a tool to be clamped is inserted into the shrink chuck, wherein the ratio of the inner diameter of the shrink chuck to the shank diameter of the tool is designed such that during subsequent cooling of the shrink chuck the tool is clamped torque-tight with the shrink chuck.

From the WO 01/89758 A1 It is known to heat the sleeve portion by means of a sleeve portion substantially coaxially enclosing, annular coil assembly by inductive means. The coil assembly is connected to a high frequency AC generator and induces eddy currents in the metallic sleeve portion which heat the sleeve portion. At the end faces and on the outer circumference of the coil assembly are magnetic flux concentrator elements of soft magnetic, electrically substantially non-conductive material, such as, for example, to prevent leakage flux and concentration of the magnetic flux. As ferrite o. The like. Arranged, which direct the magnetic flux generated by the coil assembly on the sleeve portion of the tool holder and in particular in the region of the free end of the sleeve portion.

The problem with tool holders with chucks for rotary tools, which have a cylindrical receiving shaft, is the axial migration of the rotary tool along the axis of rotation of the chuck during operation. This axial migration of the rotary tool is due to vibrations that occur during machining of the workpiece with the rotary tool. Due to this adverse effect, the workpieces can no longer be processed precisely and dimensionally. Furthermore, tilting of the rotary tool in the workpiece or even in the workpiece receiving chuck could lead to dangerous accidents. Under unfavorable conditions, even in the extreme case, the rotary tool could leave the chuck of the tool holder in operation and thus become a great danger for the machine operator.

Object of the present invention is therefore to provide a tool holder with chuck, in particular shrink chuck or the like. Available in which an axial migration of the rotary tool, such as round, profile drills, screwdriver incl. Taps, Planenker, cutters, etc., not during operation is possible, but the rotary tool is held both torque-resistant and axially with respect to the axis of rotation without emigrating.

This object is achieved by the characterizing features of claim 1, wherein expediently developments of the invention by the features in the dependent claims are created.

According to the invention, a tool holder according to the invention has a pull-out protection of the tool, which prevents axial migration of the tool from the tool holder. In this case, the pull-out securing device comprises at least one locking element and at least one corresponding thereto and the locking element receiving locking groove, which cooperate positively. In this case, the blocking element and the locking groove are formed at least teilkugelkopfartig, wherein either the chuck, the locking elements and the tool has the locking groove or vice versa. Incidentally, the Sperrnute, which are either frontally beginning on the tool shank or in the tool holder, extended respect. The groove width to be executed, so as to allow easier insertion of the tool in the tool holder.

In a particularly preferred embodiment, the tool holder on the tool holder side has at least two rotatably mounted balls, with at least two locking grooves corresponding to the balls cooperating on the rotary tool shaft in a form-fitting manner on the rotational tool side. The two locking grooves are preferably threaded on the cylindrical tool shaft, starting at the end face of the cylinder shaft along the peripheral surface of the cylinder shaft arranged. This lying on the peripheral surface of the cylinder shaft of the rotary tool locking grooves are left-wrenching tools left-hand and right-handed in right-handed rotation tools before. The locking grooves can also be formed axially and thus parallel to the axis of rotation, whereby this still acts as a rotation for the tool.

For clamping the rotary tool according to the invention such as round drills, profile drills, In the chuck according to the invention, for example shrinkage chuck of the tool holder, the induction coil is first switched on in the shrink chuck, ie the induction coil is placed under high-frequency alternating current. Due to the occurring eddy currents in the sleeve portion of the tool holder, produced by induction from the coil surrounding the tool holder, the sleeve portion is heated rapidly, so that it expands thermally and so the inner diameter of the receiving opening is increased. The rotary tool can now be inserted into the receiving opening on the shank side. The end face of the rotary tool passes to the projecting into the interior of the receiving opening balls and suggests there. Depending on the direction of inclination of the locking groove of the rotary tool, this is now turned to the left or right with respect to the axis of rotation, so that the balls can engage in the spherical grooves. The further rotation now forces a helical screwing and thus an axial retraction movement of the rotary tool in the shrink chuck or the like., Stops until the end face of the cylindrical shaft in the chuck or until the balls have reached their final position in the spherical locking grooves. The induction coil can now be switched off. Due to the rapid onset of rapid cooling, the shrinkage shrinks back to its original size, whereby the cylindrical shaft torque-tight with its peripheral surface is connected to the inner peripheral surface of the receiving opening of the shrink chuck with a press fit. Since the direction of rotation of the locking grooves correspond to the direction of rotation of the rotary tools, during operation of the tool, even under heavy load, ie high cutting resistance of the workpiece and large feed of the tool or the tool table, an axial migration of the rotary tool along the axis of rotation no longer occur. Due to the interaction of the balls in the tool holder with the ball profile-shaped locking grooves in the tool shank and the thread-like design of these locking grooves, an axial locking is generated. This axial locking can only be canceled by the rotary tool is rotated in the opposite direction to the working direction of rotation of the rotary tool while it is pulled out of the chuck. A rotation performed counter to the working direction of the rotary tool is not possible during operation, ie during the machining of a workpiece by the rotary tool. Furthermore, this rotational movement due to the torque-tight interference fit during operation is also not possible. Thus, the rotary tool can not axially move out of the shrink chuck or the like.

As a result, the machining remains accurate and dimensional accuracy can be maintained within the required tolerances. Since axial migration is avoided by the present invention, it is thus possible to produce efficiently and cost-effectively, since very little waste is produced in comparison to conventional toolholders with chucks. This also excludes another accident source and thus the risk of accidents for the machine operator.

Instead of the rotatably chucked in the chuck balls and cylindrical pins can be used with a partial or hemisphere on one of the end faces. These are instead of the balls in the bearing bore, which, for example, either require an outwardly projecting projection, so that the cylinder pin does not fall into the interior of the receiving opening, or an external thread, which is corresponding to the Innengwinde the bearing bore. The use of balls has the advantage over the use of semi-spherical head cylinder pins that the insertion of the rotary tool is easier compared to cylindrical pins because the balls are rotatably mounted and can not be misjudged compared to the cylindrical shaft. Also, balls can be held in the respective bearing bore using a threaded pin. In this case, the cylinder pin itself on its front side on a ball receiving training, for example. In the form of a polygonal recess or a spherical indentation o. The like .. Instead of the threaded pin and dowel pins, o. The like. Can be used.

The extract safety of tools according to the invention, in particular rotary tools in tool holders with a tool holder, is particularly suitable for chucks, such as collet chuck, HG chuck, hydraulic chuck and shrink chuck.

Conveniently, the Sperrnute are formed differently depending on the requirement in the peripheral surfaces of the shaft of the tool. The Sperrnute may have from the front side of a different Sperrnutverlauf. This can be helical, L-shaped, curved or formed from composite section-wise straight and / or curved cylindrical surface paths. In particular, in a helical Sperrnutverlauf the direction of rotation must correspond to the direction of rotation of the grooved tool. Ie. if the tool has been grooved to the left, the helical locking groove must be on the left rising, and on the right grooved tool, on the other hand, it must be right-angled. Therefore, there is also a blocking effect of the pull-out protection.

In a further embodiment, the shank of the tool has an external thread on the end side and the tool holder of the tool holder has a corresponding internal thread. In this case, the pull-out protection is carried out using the external thread on the tool, which is formed on the left-hand side with left-grooved tool and the right-hand with right-hand grooved tool. In this embodiment, locking elements and locking grooves become obsolete.

In a particularly preferred embodiment, the bearing bores which receive the locking elements are preferably formed continuously from the outer peripheral surface of the tool holder to the interior of the tool holder receiving into the tool. In this case, these bearing bores may be formed to be cutting perpendicular to the axis of rotation of the tool holder and the axis of rotation and / or be formed tangentially adjacent to the inner peripheral surface of the tool receiving interior. Preferably, the longitudinal axes of the bearing bores are mutually equiangular and in particular arranged in a plane perpendicular to the axis of rotation of the tool.

In a further particularly preferred embodiment, in particular for tool holders with shrink chuck, the balls are mounted as locking elements in a ball cage. In this case, the bearing bores for the respective balls in the ball cage with respect to the inner peripheral surface each have a smaller bore diameter than the bearing bore diameter. As a result, the balls can not fall inward into the interior of the tool holder, but only overhang the inner region of the ball cage. The ball cage can either be inserted positively as a separate component in the interior of the tool holder, or be incorporated in a sleeve. In this case, the sleeve has the respective bearing bores with respect to the interior lying smaller bearing bore diameters. The sleeve can be pressed into the interior of the tool holder, shrunk, welded to the tool holder, positively held with additional threaded pins and / or with locking elements and locking grooves on the sleeve, as described according to the invention were described on the shaft of rotary tools.

In a particularly preferred embodiment, in particular for shrink chuck, the pull-out protection additionally has a device which enables a play-free holding of the tool with the safety catch. In this case, the tool is pressed in the direction of the tool holder in the direction of the tool holder by a force exerting element, which is, for example. Concentric to the axis of rotation of the tool at the bottom of the hole. As a result, the pull-out protection is free of play on the tool. For even a small clearance between the pull-out protection and the tool, the tool allows a certain freedom of movement, which can already lead to damage to the tool cutting. In particular, as a force-exerting element compression springs in the form of coil springs, conical springs, disc springs and disc spring assemblies and / or elastic or rubber-elastic elements are possible.

In a further and particularly advantageous embodiment for a tool holder with a minimum amount of lubrication, this has at least one transfer piece for the minimum quantity lubrication that comprises at least one, preferably a plurality of channels for the pressure build-up or pressure compensation. For such a tool holder with such a transfer piece is optionally sought independent of the pull-out protection separately protection. The transfer piece, preferably in the form of a tube, which can also be composed of several parts, is preferably formed with a radial flange and preferably movably received and guided in a bore located in the tool holder. The tube, which may also have different cross-sectional profiles, is preferably biased by a coil spring mounted in the tool holder, wherein the cylindrical shaft of the tube preferably penetrates the coil spring. Of course, other force-exerting elements such as tension spring, conical spring, disc spring, and / or elastic elements and combinations thereof are possible. The spiral spring is preferably arranged between the radial flange of the tube and, for example, a stop bottom in the tool holder, whereby the tube is mounted biased relative to the tool holder. The transfer piece is preferably sealed in the bore. In this case, the tool holder concentric with the bore for the transfer piece or pipe, for example, at least one shaft seal and / or other sealing elements such as sealing rings, sealing lips, etc., which may also be arranged in the tool holder and / or on the transfer piece or on the pipe itself. The channels in the form of through holes, in particular with circular cross-sectional profile, wherein other cross-sectional profiles are possible, are preferably arranged in the radial flange of the transfer piece, so that the through hole in the transfer piece are connected to the through hole in the radial flange of the transfer piece. Along the cylindrical peripheral surface of the radial flange of the transfer piece a radial recess is arranged. Therein, preferably one of the radial recesses corresponding preferably cylinder surface portion-shaped annular membrane is embedded in a form-fitting manner. It can Both the Umfangsflächenausnehmung, in particular in the form of a groove, as well as preferably corresponding thereto cross section of the embedded membrane in the groove, for example. Have a Teilkugelkopfprofil or other profiles. The ring membrane is preferably formed of an elastic material, in particular of a rubber-elastic material, but other materials are possible, such as carbon fiber material, plastics, Teflon and flexible metals. The channels for the pressure equalization or pressure build-up are in particular connected to the membrane and the interior of the transfer piece. In a pressure build-up in the tool holder, the diaphragm therefore bulges radially and thus abuts against the peripheral surface of the receiving bore of the tool holder. As a result, the transfer piece is locked against axial adjustment.

In the following, embodiments of the invention will be explained with reference to drawings. In it shows in a purely schematic representation:

1 a sectional view of the tool holder according to the invention with shrink chuck with separate not yet clamped and provided with locking grooves end mill,

2 a sectional view of the tool holder according to the invention with shrink chuck and clamped end mill according to the invention.

3 a sectional view of the tool holder according to the invention with collet chuck and clamped end mill according to the invention.

4 a sectional view of the tool holder according to the invention with HG-chuck and clamped end mill according to the invention.

5 a sectional view of the tool holder according to the invention with Hydrodehnspannfutter and clamped end mill according to the invention.

6 a sectional view of the tool holder according to the invention with clamped end mill according to the invention, wherein the tool has an external thread and is screwed into a corresponding internal thread of the tool holder.

7 a sectional view of the tool holder according to the invention with balls as locking elements, which are secured by threaded pins.

8th a sectional view of the tool holder according to the invention with balls as locking elements which are secured by threaded pins, wherein the balls are partially recessed in the grub screws.

9 a sectional view of the tool holder according to the invention with balls as locking elements, secured with cylindrical pins in a press fit.

10 a sectional view of the tool holder according to the invention with one-piece locking element, which is a threaded pin with spherical shape on one of its end faces.

11 a sectional view of the tool holder according to the invention with one-piece locking elements, which are cylindrical pins with spherical shape on one of the end faces, in press fit.

12 a sectional view of the tool holder according to the invention with balls in a separate ball cage, adjacent to a sleeve.

13 a sectional view of the tool holder according to the invention with balls, which are arranged in a incorporated in the sleeve ball cage, wherein the sleeve is pressed or shrunk.

14 a sectional view of the tool holder according to the invention 13 wherein the sleeve is welded to the tool holder.

15 a sectional view of the tool according to the invention from 13 , wherein the sleeve is mechanically fixed with screws with cone dome.

16 a sectional view of the tool holder according to the invention with a slotted sleeve which receives the balls, and the sleeve is provided with locking grooves on other balls and screws on the tool holder is held.

17 a sectional view of the tool holder according to the invention with a conical spring for a backlash-free safety guard.

18 a sectional view of the tool holder according to the invention with a Längeneinstellschraube, which is formed of rubber-elastic material.

19 , a sectional view of the tool holder according to the invention with a length adjustment screw which has integrated therein an element made of rubber-elastic material.

20 a sectional view of the tool holder according to the invention with a Minimal quantity lubrication, balls as blocking elements and a membrane made of rubber-elastic material.

21 a sectional view and side view 20 the tool holder according to the invention with tangential arrangement of the blocking elements.

22 an enlarged view of an area 20 the tool holder according to the invention with the membrane and a pressure channel in the transfer piece.

1 schematically shows the tool holder in a sectional view 1 and an end mill as an example 2 that are related to each other with respect to a rotation axis 3 are arranged. The tool holder 1 has at least two, preferably three or four balls 4 on. The ball is located in a bearing bore 5 , which are perpendicular to the axis of rotation 3 and thus to the longitudinal axis, in the sleeve section 6 of the tool holder 1 is arranged. This bearing bore 5 is a through hole and extends from the outside of the sleeve portion 6 to the inner peripheral surface receiving opening 7 which are concentric with the axis of rotation 3 in the tool holder 1 is arranged. The warehouse front 8th the bearing bore 5 is in the form of a spherical cup and according to the spherical shape of the ball 4 trained so that the ball 4 partly in the interior of the receiving opening 7 protrudes. The ball 4 is by a grub screw 9 in its forward position, that is in one of the interior of the receiving opening 7 projecting position held, while the bearing bore 5 one to the external thread of the threaded pin 9 corresponding internal thread on. The length of the threaded pin 9 does not protrude over the outer surface of the sleeve portion 6 out. The grub screw 9 has a hex socket 10 on. The end mill 2 points to his cylindrical shaft 11 near the front 12 the helically arranged locking grooves 13 . 14 on. These correspond to the spherical shape of the sphere 4 a spherical profile. To fully clamp the end mill in the tool holder, it must be in the direction of rotation when inserting the end mill 15 be turned so that the end mill 2 axially helically in the receiving opening 7 is screwed in until the end mill 2 has reached a stop.

2 shows purely schematically in a sectional view of the tool holder 1 in which the end mill 2 is completely clamped. The end mill 2 is located up to its stop with its cylindrical shank 11 in the receiving opening 7 , This is where the ball attacks 4 , held by the grub screw 9 , in the locking groove 13 respectively. 14 , In this diagrammatic sectional view is the cylindrical shank 11 in a press fit with the receiving opening 7 ; ie the induction coil (not shown in the drawing) is off and the shrink chuck of the tool holder 1 has cooled and shrunk back to its original size. As in 2 can be clearly seen, an axial movement of the end mill 2 along the axis of rotation 3 not be done, because the ball 4 in the spherical locking groove 13 respectively. 14 in the cylindrical shank 11 sits, making a movement along the axis of rotation 3 Is blocked. Thus, in this drawing, the interaction between ball 4 and locking groove 13 respectively. 14 clearly in the form of a lock. To remove the end mill 2 from the tool holder 1 must only after switching on the induction coil of the end mill 2 contrary to the direction of rotation 15 (please refer 1 ) and in the axial direction along the axis of rotation 3 from the tool holder 1 be pulled out.

In the following figures possible embodiments are shown as the pull-out protection is formed in other commercially available chucks.

3 shows a schematic sectional view of a conventional collet chuck with union nut with the pull-out protection according to the invention by the Sperrnute and balls.

4 shows a HG-lining with the pull-out protection according to the invention by Sperrnute and balls.

5 shows in a purely schematic sectional view of an ordinary Hydraulic expansion chuck with inventive pull-out protection through the Sperrnute and balls.

6 shows in a purely schematic sectional view of a tool holder in the form of a shrink chuck, the end mill with the tool via a thread 16 screwed together. Due to this screwing, which is formed rising left in left-grooved tool and right rising in rechtsgenutetem tool, an axial pull-out protection of the tool is achieved from the tool holder.

7 shows in a purely schematic sectional view of a shrink chuck with locking elements in the form of balls 4 , which in the respective bearing bores 5 with grub screws 9 being held. The grub screw 9 has a blunt end face.

8th shows in a purely schematic sectional view of a shrink chuck with locking elements in the form of balls 4 , which in the bearing bores 5 through threaded pins 9 being held. Set screw 9 indicates at the the ball 4 receiving end face a recess 17 on. The recess 17 is in the form of a blind hole or, for example, formed in the form of a hexagon socket corresponding to the diameter of the ball.

9 shows in a purely schematic sectional view of a shrink chuck with locking elements in the form of balls 4 , which in the bearing bores 5 by passport 18 being held. Due to the interference fit between the dowel pin 18 and the bearing bore 5 are the blocking elements in the form of balls 4 fixed in their position.

10 shows in a purely schematic sectional view of a shrink chuck with one-piece locking elements 19 , blocking element 19 is a threaded pin, which on one of its front sides a hemisphere head 20 having.

11 shows in a purely schematic sectional view of a shrink chuck with one-piece locking element 19 in the bearing bores 5 , The one-piece locking elements 19 are dowel pins, which are connected in press-fit with the shrink chuck. The one-piece locking elements 19 have on one of their faces a hemisphere head 20 on.

12 shows in a purely schematic sectional view of a shrink chuck with locking elements in the form of balls 4 , The balls 4 are in a ball cage 21 stored. Here is the ball cage 21 at the opening reason of the receiving opening 7 arranged. Adjacent there is a sleeve 22 , In the cage 21 are the balls 4 let in, which are pressed by the cage radially outward. The balls 4 are pressed against a shoulder that extends between the receiving opening 7 and a free rotation at the end of the receiving opening 7 located. At this shoulder, the balls can 4 support axially. If the tool is shrunk, the balls are 4 also supported internally and so can both the tool 2 as well as the sleeve 22 secure against an axial extension.

13 shows in a purely schematic sectional view of a shrink chuck with the balls 4 which are in a sleeve 22 in the left portion of the sleeve and in the receiving opening 7 are located. The left section of the sleeve 22 acts as a ball cage for the balls 4 , The bearing bores 5 for the balls 4 in the sleeve 22 with respect to the inner circumferential surface of the sleeve 22 a smaller diameter than the diameter of the balls or the bearing bore diameter. Thus, the balls can 4 protrude into the interior, but not fall into it. The sleeve 22 is either shrunk or pressed into the feed.

14 shows in a purely schematic sectional view of a shrink chuck with balls 4 in a sleeve 22 , The sleeve 22 is with the sleeve section 6 with a weld 23 connected. The welding of the sleeve 22 With the shrink chuck can be selectively, partially or annularly formed as a closed example. Y-seam.

15 shows in a purely schematic sectional view of a shrink chuck with balls 4 in a sleeve 22 , In this embodiment, the sleeve 22 via threaded pins 24 fixed with the tool holder. This is where the set screws point 24 For example, a cone on. Of course, other training, such as. A ball head, etc. possible. To the frontal design of the threaded pins 24 has the sleeve 22 corresponding depressions 25 on, which correspond to the frontal dome formation of the setscrews 24 are formed. In the present embodiment, these depressions 25 formed cone-shaped. For fixing the sleeve 22 on the tool holder is at least one threaded pin 24 with a frontal training, eg. In the form of a cone necessary. Preferably, three, more preferably four setscrews for fixing the sleeve 22 arranged on the tool holder.

16 shows in a purely schematic sectional view of a shrink chuck with the in the sleeve 22 arranged locking elements in the form of balls 4 , The sleeve 22 is designed thick-walled, as in the previous figures. Therefore, the sleeve 22 slotted (not shown in the drawing). In this embodiment, the sleeve 22 also connected by balls with the tool holder. These are located in the left area of the sleeve 22 locking grooves corresponding to the balls 27 , which also have a ball profile. As the tool in the shrink chuck is axially fixed by the interaction of locking elements and locking grooves, in this case, the sleeve 22 over balls 26 as blocking elements with locking grooves 27 in the outer peripheral surface of the sleeve 22 axially fixed. The balls 26 are located in bearing bores 28 , which in turn threaded pins 29 connected by a thread. Also in this case, the bearing bore 28 in the inner area in the direction of the receiving opening 7 a smaller diameter than the bearing diameter, which is the ball diameter of the ball 26 equivalent. Thus, the ball can 26 do not fall into the interior, but they protrude into it.

17 shows in a purely schematic sectional view of a shrink chuck with an axial pull-out protection according to 2 , In addition, the tool holder has a conical spring 30 on which is located between the front 12 of the cylindrical shaft 11 of the end mill 2 and the floor 31 the receiving opening 7 located. The compression spring in the form of a cone spring 30 presses on the face 12 of the end mill 2 in the direction of the axis of rotation 3 from the tool holder 1 out. Thus, a possible clearance or manufacturing tolerances of Sperrnute in the peripheral surface of the cylinder shaft 11 and the location of the balls 4 in the tool holder 1 eliminated, in that the end mill 2 in the axial direction by the force of the conical spring 3 is additionally locked. Thus, even a small clearance between the axial safety catch and the tool can be eliminated. Thus, you do not run the risk of additionally damaging the tool cutting edges during operation due to small manufacturing tolerances.

18 shows in a purely schematic sectional view of a shrink chuck with the locking elements in the form of balls 4 , Here, the backlash-free pull-out protection of the tool after shrinking by using a Längeneinstellschraube 32 , which is preferably formed of a rubber-elastic material. To the length adjustment screw 32 is in the tool holder corresponding to an internal thread 33 educated. In 18 In addition, another embodiment of the Sperrnutverlauf is shown. In this embodiment, the locking groove 34 in the form of an "L", but starting at the front 12 of the cylindrical shaft 11 , educated. This is a quasi bayonet-like lock for axial blocking as a pull-out protection of the tool created from the tool holder.

19 shows in a purely schematic sectional view of a shrink chuck 18 , concentric with the length adjustment screw 32 an integrated therein elastic element 35 is arranged. In this case, the elastic element 35 preferably formed of a rubber-elastic material. The play-free pull-out protection takes place via the contact force, which is achieved by the length adjustment screw 32 on the elastic element 35 over the front side 12 on the end mill 2 is exercised.

20 shows in a purely schematic sectional view of a shrink chuck, with a minimum quantity lubrication (MQL). The axial pull-out lock is via locking elements 36 , which in turn are formed in the form of spheres. Concentric with the axis of rotation inside the shrink chuck, there is a slidable tube 37 , which is the transfer piece for the minimum quantity lubrication. The pipe 37 is due to the spring force of a coil spring 38 pressed against the tool shank (not shown in the drawing). In the 20 are two possible end positions of the pipe 37 shown. The right-lying contact surface of the tube with the tool shank is conical in the form of a radial tube flange 39 educated. The spiral spring 38 is doing through the pipe 37 penetrated concentrically. The spiral spring 38 is located between the ground 31 and the conical section peripheral surface of the tube 37 at the radial neck flange. 21 shows along the section line AA 20 in a purely schematic sectional view, the tangential arrangement of the locking elements 36 in the tool holder. 22 shows an enlarged detail of a section 20 , which is marked with a dashed line. In the radial neck flange 39 of the pipe 37 are through holes 40 arranged, which differ from the inner diameter of the tube 37 to the outer peripheral surface 41 of the radial pipe flange 39 extend. Along the cylindrical peripheral surface 41 of the radial pipe flange 39 of the pipe 37 is a concentric cylindrical surface-shaped recess 42 arranged, whose width is preferably smaller than the width of the cylinder peripheral surface 41 of the pipe flange 39 is. Corresponding to the recess 42 is an annular cylindrical surface portion-shaped membrane 43 arranged, which are flush with the outer cylinder peripheral surface 41 of the tube bottle 39 is formed. The membrane 43 is preferably formed from a rubber-elastic material. This membrane 43 along the peripheral surface 41 seals the pipe 37 against the wall of the receiving opening 7 from the shrinkage lining. The holes 40 which radially to the inside of the membrane 43 lead, direct the air pressure to the membrane 43 continue, which thus to the bore wall 7 is pressed. As a result of the pressure build-up, the membrane bulges radially, thus laying against the inner peripheral surface of the receiving opening 7 of the tool holder. Thus, the pipe becomes 37 secured as a transfer piece for the minimum quantity lubrication against axial adjustment. Through the sliding tube 37 the lubrication mist can be transferred to the tool without loss.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• WO 01/89758 A1 [0003]

Claims (21)

System of tool holder and tool, wherein the tool holder has a cylindrical tool holder, preferably a chuck and therein the cylindrical shank of the tool, in particular rotary tool is received, the system having an axial emigration of the tool locking extract safety, which at least one locking element and at least one for this purpose and the blocking element receiving locking groove includes, which cooperate form-fitting manner, wherein the locking groove in the peripheral surface of the shaft of the tool and the locking element in the chuck or vice versa, characterized in that the Sperrnutverlauf helical, L-shaped, curved or made of composite sections rectilinear and / or curved cylindrical surface paths is formed. Tool holder according to claim 1, characterized in that the blocking element and the locking groove are formed at least teilkugelkopfartig. Tool holder according to one of the preceding claims, characterized in that the chuck is in particular a collet chuck, a HG chuck, a hydraulic expansion chuck or a shrink chuck. Tool holder according to one of the preceding claims, characterized in that the tool, in particular rotary tool, at least one, preferably two, more preferably four locking grooves. Tool holder according to claim 4, characterized in that the locking grooves are arranged in the peripheral surface of the shaft of the tool, wherein the locking grooves extending from the end face extend at least over a partial section of the shaft. Tool holder according to claim 1, characterized in that the chuck has a thread (1b), with which the tool can be screwed via a thread on the tool shank. Tool holder according to claim 6, characterized in that the helical Sperrnutverlauf is formed on the left-hand tool left-hand and right-handed in rechtsgenutetem tool. Tool holder according to one of the preceding claims, characterized in that the shank of the tool has an external thread on the end side, with left-hand tool, the outer thread is left-hand and right-widened tool, the outer thread is formed rechtssteigend, and the tool holder has a corresponding internal thread. Tool holder according to one of the preceding claims, characterized in that the arrangement of the locking elements in the tool holder and, correspondingly, the arrangement of the locking grooves on the tool, are preferably equiangular to one another. Tool holder according to one of the preceding claims, characterized in that the blocking elements are arranged in the tool holder, in particular in a plane perpendicular to the axis of rotation of the tool. Tool holder according to one of the preceding claims, characterized in that the blocking elements in the tool holder balls, pins, bolts and / or setscrews, which have at least one and at least teilkugelkopfartigen frontal convex training are. Tool holder according to claim 11, characterized in that the locking elements are preferably formed in the tool holder made of alloyed stainless steel, wherein preferably at least the balls and / or the teilkugelkopfartige area of the locking elements are hardened. Tool holder according to one of the preceding claims, characterized in that the blocking elements are mounted in bearing bores in the tool holder, wherein the bearing bores preferably extend continuously from the outer peripheral surface to the tool receiving the interior of the tool holder, and these are formed either perpendicular to the axis of rotation of the tool holder and / or tangentially adjacent to the inner peripheral surface of the tool receiving interior. Tool holder according to one of the preceding claims, characterized in that the locking elements in the bearing bores are preferably held by threaded pins and / or by press-fitting, and / or the locking elements are formed with external threads which are formed corresponding to internal threads formed in the bearing bores. Tool holder according to one of the preceding claims, characterized in that the locking elements protrude in its stored position in the bearing bores with the ball-head-like formation in the interior of the tool holder receiving the tool at least partially. Tool holder according to one of the preceding claims, characterized in that the blocking elements, in particular balls in tool holders, in particular shrink chuck, are mounted in at least one ball cage, wherein the bearing bores for the balls of the ball cage with respect to the inside have a smaller diameter than the bearing bore diameter. Tool holder according to claim 16, characterized in that the tool holder has at least one ball cage in the interior of the tool holder, wherein the ball cage as a separate component, incorporated in a sleeve or a ball cage having sleeve, wherein the sleeve is pressed, shrunk, welded to the tool holder , held positively with threaded pins and / or with locking elements and locking grooves on the sleeve, is fixed. Tool holder according to one of the preceding claims, characterized in that the tool with the pull-out, in particular in shrink chucks, axially play by force-applying elements is held, in particular with at least one compression spring, conical spring, coil spring, disc spring and spring assemblies, and / or rubber-elastic elements. Tool holder according to one of the preceding claims, characterized in that the tool with the pull-out protection, in particular with feeds with minimum quantity lubrication, is axially free of play, wherein the transfer piece for the minimum lubrication has at least one through hole in the conical radial flange portion, the radial flange of the transfer piece along its cylindrical circumferential surface has a radial recess, wherein a cylindrical surface portion-shaped annular membrane vorzugsweiseingeformschlüssig and embedded embedded flush, preferably formed of rubber-elastic material, wherein the through holes extend radially from the interior of the transfer piece to the membrane. Tool holder for use in a system according to any one of the preceding claims, characterized in that the tool holder has the features relating to the tool holder of one or more of the preceding claims. A tool for use in a system according to any one of claims 1 to 13, characterized in that the tool comprises the tool-related features of one or more of claims 1 to 13.

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