WO1991008072A2 - Clamping system for connecting parts so as to prevent their rotation or cyclic motion - Google Patents

Abstract

Clamping system for connecting parts, in particular workpiece parts (as well as multi-part workpieces), for example face milling cutters connected to thread-cutting disks, drills and the like, so as to prevent their rotation or cyclic motion. One part, for example a tool part, is connected to another part, for example a tool holder, by means of tapers with a bayonet lock or by means of tapered close-tolerance screw threads. The total length of the cutting tool and the tool shank (or the extension of the tool) is practically constant irrespective of their respective axial lengths. The tool holder is very slim and lightweight. Drilling tools in particular are provided with a predetermined breaking point.

Description

 Clamping system for connecting parts, especially tool parts, in a rotationally and concentrically safe manner

The invention relates to a generally usable clamping system, but in particular to a clamping system for connecting tool parts including multi-part tools, such as tools and tool extensions, in a rotationally and concentrically secure manner, in which a conical section of the tool shaft is received in an inner cone of the tool extension.

For the connection of parts, in particular for the connection of driven parts to ensure rotation and true running, a clamping system is desirable which, on the one hand, meets all requirements and, on the other hand, enables the parts to be connected quickly without losing individual parts and without the clamping system requires a special manufacturing effort. Such a connection of parts very often occurs, for example, but by no means exclusively when connecting parts of multi-part driven tools to one another or with their clamps in a rotationally and concentrically secure manner.

A multi-part tool can consist, for example, of a face milling cutter which produces a core hole and a cutting ring which can be connected to this for producing internal threads.

Clamping systems consisting of a conical section of the tool shank and an inner cone on an associated tool part or a tool holder are known per se for tools, in particular drilling tools, but these known clamping systems have the disadvantage that the clamping system does not have any tensile forces can be transmitted so that these known clamping systems cannot be used on their own where axial tensile forces occur during tool operation, such as in milling cutters. In such cases, the tool or its extension must be additionally fastened

REPLACEMENT LEAF are what is usually done by means of a pull-in screw that is coaxially aligned with the tool and can be inserted from behind and is therefore associated with additional work. Such additional work also occurs in other known systems, such as, for example, the system for tensioning taper shanks known from DE-GM 76 09 688, in which the tensioning means is formed by a screw cross wedge to be used and tightened. With simple tools such as drills or their extensions cone _can sit be sufficient as clamping system, in most cases, but it is a erflache Mitrieh be required to provide a safe rotational drive to reach the tool. The known clamping or clamping systems are unsatisfactory not only because of the additional work or time required for this, but also because of the fact that they have to be constructed in several parts and therefore also contain lost individual parts.

Furthermore, the known clamping systems of the type in question here for clamping very small tools are completely uneconomical, so that such tools are equipped with a cylindrical shank, which in turn then requires the use of a chuck or a drill chuck.

In drill presses, in particular drill stands with a small stroke, it is a general problem with the same stroke setting in several work steps, for example screw holes or threaded holes with centering and countersinking, to produce holes which are to be produced because of the very different lengths of the tools to be used in succession the stroke of the drilling machine is not sufficient to be able to carry out the required operations with one setting. It is therefore imperative to make an adjustment or readjustment taking up the centering or bore that has already been created.

Furthermore, e.g. For the special case of impact drills, mention should be made of the not inconsiderable weight of the drill chuck which considerably impairs the achievable impact force.

MARINE LEAF The object of the invention is to create a clamping system which can be produced at low cost and which can be handled with the least possible work, in particular a clamping system which can be used as a tool clamping system and which, while ensuring the rotary drive and concentricity of the tool required for tool drives, also for transmitting axial Forces is suitable. Furthermore, a design that is adaptable with the least possible workload of the respective work task, for example the production of counterbored holes, is to be created, which permits ^" uniform work with a drilling machine and within certain limits also means and ways for the easiest possible representation or handling and to provide absolutely reliable tool retrofitting with regard to the secure setting of the required rotary drive and concentricity of a tool. Furthermore, the clamping system as a whole should have the lowest possible weight in order to improve the effect of impact drilling machines at the same time.

This object is achieved according to the invention essentially by the fact that the tool can be locked in a rotationally and concentrically secure manner by means of a bayonet locking mechanism via its conical tool shaft in a correspondingly conical receiving recess by means of a bayonet locking mechanism, the bayonet locking mechanism comprising at least one for the most part part consists of its circumference out in an internal recess of the inner cone, in particular a tool extension, aufgenom¬ menen ball and on the outer circumference of the correspondingly conically constructed, ^'to be clamped part, in particular the Werk¬ generating shaft arranged obliquely, in particular schraubenlinien- shaped rising circumferential groove, and wherein the ball engages in the circumferential groove almost without play.

In an expedient embodiment, it is provided in detail that the ball (s) forming part of the bayonet lock are accommodated for the most part of their circumference in the inner recess of the tool extension

REPLACEMENT LEAF and the circumferential groove arranged on the outer circumference of the milling cutter is designed to rise in the shape of a screw line in such a way that a kind of helical gear is created by the rotary movement of the tool drive.

In a preferred embodiment of the invention, it is further provided that the tool shank optionally has a further region which tapers conically towards its free end and that a cutting ring projecting radially from a face milling cutter diameter can be placed on the tool shank as a threading device with an inner bore corresponding to the milling shank , in order to produce a rotationally secure connection between the tool shank and the cutting ring, it is further provided that the tool sheep and the cutting ring have a cross-sectional shape that deviates from the pure circular shape, such that they engage in one another in a rotationally secure manner by means of mutually arranged axial lugs and recesses.

In order to achieve a play-free entrainment of the cutting ring by the tool sheep, it is provided that the recess in the cutting ring associated with the axially directed, polygonal, in particular square cross-sectional shape has a larger cross section in the cutting ring and is in particular dimensioned such that the cross section the recess in the cutting ring prevents the axial projection on the tool shaft engaging in the recess from turning, so that during operation of the tool equipped with the cutting ring a mutual wedging between the cutting ring and the tool shaft is achieved, each any play or tolerance-related play between the mutual engagement means is automatically and reliably eliminated.

To further compensate for any manufacturing-related tolerances and resulting irregularities in the drive or the concentricity, the invention further provides that at least when the cutting edge is placed on the tool sheep

REPLACEMENT LEAF a resiliently elastic ring is inserted between the adjacent end faces of the tool extension and the cutting ring, which ring can be formed in detail either by a ring made of resilient plastic or rubber material or by a metal spring, in particular a plate spring. The desired preload of the resiliently elastic ring during operation of the tool is reinforced by the design of the bayonet lock, which generates an axially directed clamping force as a result of the helical slope of the circumferential grooves in the milling shank.

When using the clamping system in connection with milling cutters, a particular advantage of the design according to the invention can also be seen in the fact that when the same thread milling cutter is used, simply by exchanging the milling cutter extension, different recesses or. Thread recess depths worked and even simultaneously, i.e. can be provided with a countersink in one work step, the base holder equipped with the countersink or the cutting edges not needing to be changed.

According to an expedient development of the bayonet lock, it is provided that a plurality of radial groove recesses are arranged in the tool shaft and associated balls, which are partially accommodated in recesses of the tool extension, distributed over the outer circumference of the tool shaft and the inner circumference of the tool extension. the radial groove recesses in the tool shank being arranged parallel to one another.

In order to reduce the local surface load of the bayonet lock, provision can furthermore also be made for the bayonet lock to be provided by at least one radial one, which is partially received in a recess in the tool extension and is arranged in an inclined manner in the axial direction or as a helix in the outer circumference of the tool shaft Bolt engaging circumferential groove is formed.

REPLACEMENT LEAF A reverse arrangement of the parts of the bayonet lock is of course within the scope of the invention, in particular it can also be provided that the balls or the bolts are arranged in the driven part, for example milling cutter shank, and the associated groove recesses are arranged as inner circumferential grooves in the driving part, for example milling cutter extension are.

A particular relief in the handling of the tool or the parts of the tool when inserting and loosening results from the fact that on the conically shaped mutual contact surfaces, e.g. a lubricant is applied to the milling shank and / or the milling cutter extension, and almost all parts have a width across flats.

Finally, within the scope of the invention, a general use of the principle shown above of mutual clamping of tool parts and / or tools with tool holders is provided, in that the connection of all rotary driven parts as well as the connection of all non-rotary driven parts, such as tool, tool extension or tool holder with the respective receiving part, a bayonet lock is switched on according to one of the configurations shown above. For example, in the case of machine tools, in particular milling machines, which are not equipped with an automatic tool changer, the use of the previously required tool tightening spindle could be dispensed with, since the conical design of the shank and receptacle in connection with a correspondingly designed insertion slot ensures a smooth running within certain limits torsion-proof clamping also ensured for different shaft diameters, the assembly being carried out by simply screwing the shaft in or out from the receptacle from the outside.

In a further embodiment of the inventive concept, the required number of tool holders of a machine can be achieved

REPLACEMENT LEAF - / - The use of simple reducing sleeves, for example a type of cut-off drilling sleeves, can be reduced in connection with the clamping system according to the invention, since in this way, with the largest possible tool holder, all tool sizes can be clamped, with regard to handling, particularly It is advantageous that only the reducing sleeve needs to be unscrewed from the tool holder by means of an open-end wrench and the rest of the tool holder or the reducing sleeve remains on the machine. This is particularly advantageous in the case of larger machines equipped with heavy tool holders, because their handling is made considerably easier. This also applies in the event that, in addition to the bayonet lock, a reverse rotation lock formed from a number of screws arranged tangentially in the wall of the receiving driving part and associated radial support surfaces on the circumference of the driven part is switched on in the connection. In a modification in which the screws and the radial surfaces assigned to them are set at an angle, for example in the region of 30 °, this configuration also enables the generation of a tensioning effect.

As part of the further development of the inventive concept, the bayonet lock can also be used in other machines equipped with tools to be clamped, for example drilling machines, with the advantage of simplifying the equipment and handling. In particular, the use of the bayonet lock according to the invention enables not only the replacement of the usual drill chucks and milling chucks, but also the use of milling cutters on drilling machines, since on the one hand it enables clamping of tools of all sizes with absolute rotation and concentricity, and on the other hand it can support an axial pull on the tool.

Furthermore, the application of the inventive concept, due to the safe operation of the bayonet lock, can also apply to the clamping of non-rotary drives Tools such as pushing or pushing tools.

Finally, the application of the inventive concept can also extend to hose or line couplings as a result of the axially lock-out mode of action of the bayonet lock, where necessary all non-rotationally driven connections additionally with a tensioning device or rotation lock, in particular in the form of with corresponding surfaces interacting support screws and can also be equipped with seals.

In a further perfection of the adhesive system shown above using the example of the mutual connection of tool parts, the invention also provides here, for example, the connection of tool parts, that the clamping of the cutting tools via cones and conical fitting threads or cones with a bayonet lock and that here, regardless of the respective axial length of the cutting tool, cutting tool and tool extensions, together always have an at least approximately constant overall length.

This allows the setting of the machine to be kept constant irrespective of the length of the tool used in each case, so that any additional work for setting work can be eliminated when changing the tool. The clamping of the tool via conical engaging and receiving parts also brings with it the advantage of clamping the tool considerably simplified compared to the chucks used hitherto and also of a considerably lower dead weight. Above all, this results in better concentricity and absolutely safe tool turning.

According to a first embodiment of the invention, provision can be made for each given length of a tool to be one

ER ^SA TZBLATT corresponding length of an extension is assigned.

However, this embodiment of the invention requires a corresponding length of the tool shank for each given tool length, so that a large number of tool shanks corresponding to the existing number of tool lengths must be stored, selected and used.

According to a preferred embodiment of the invention, it is therefore provided that the tool shank is formed in several parts.

The tool shank is particularly advantageously formed in two parts and consists of a conical clamping part and an extension part connectable to this. In detail, it is expediently provided that the cutting tool, the extension part and the clamping part can be connected to one another via conically shaped, mutually arranged end regions and end region recesses, the extension part having an axial conical recess on its end face associated with the connection of the cutting tool and on its clamping part associated end has a conically shaped end region.

On the one hand, in particular in the case of hand drills, the extensions, as in the proposal according to the main application, can be accommodated via a bayonet lock on a receiving sleeve connected to the working spindle of the machine tool instead of a conventional drill chuck via an internal thread or internal or external cone, and on the other hand , in particular in the case of upright drilling machines which are connected to the work spindle of the machine tool by means of a bayonet lock and equipped with appropriate receiving sleeves.

In order to also be able to fix the tool to the respective receptacle in a simple and economical, concentric and rotationally secure manner, the connection between the tool and the receptacle should be in the manner of a conical fitting thread

ERSA _T Z _B LATT be designed to avoid the disadvantage of the more complex manufacture of a bayonet lock, particularly in the case of tools of smaller diameter. On the other hand, even with larger diameters, in which several balls or bolts and insertion slots are provided, the production is technically difficult and complex.

It should also be noted that in the case of tools working in the full material, especially center drills or stone drills, a connection between the tool and receptacle or tool shank and tool as well as extension over smooth cone-shaped surfaces is sufficient, since full material occurring axial resistance the tool always remains adequately connected to the holder. Finally, the very slim design of the clamping of the tool or extension or receiving sleeve should also be advantageous in general use.

With regard to the configuration of the mutual connection between the cutting tool and the tool sheep or this and an extension, according to one feature of the invention it can be provided that the conical outer surfaces of the conical end region of the cutting tool and the conical end region recess of the extension or the conical clamping part and the clamping sleeve are subdivided into a helically increasing surface by a spiral-shaped circumferential groove recess and likewise a spiral-increasing circumferential web, the circumferential groove on the one hand and the circumferential web rib on the other hand having non-congruent triangular cross-sectional shapes.

In order to ensure with such a configuration of the conical jacket surfaces which ensure the concentric mounting or clamping of the cutting tool and / or tool shank or extension, it is proposed that all radial and axial forces in the tightening direction are absorbed or transmitted exclusively via the cone surfaces and around this

REPLACEMENT LEAF To achieve it is also provided that the cross-sectional shapes of the grooves and the web ribs are designed so that they enclose a gap-shaped free space between them when the tool or the extension is clamped in with their flank surfaces facing away from the working direction of the tool. The grooves and web ribs can have an acute-angled triangular cross-sectional shape with a radius or a chamfer, but can also have a different shape for the purpose of a conical screw connection. As a result of this design it is achieved that the flank surfaces of the grooves and web ribs facing the working direction of the cutting tool become effective only when the tool or tool shaft is being clamped or extended in the sense of a feed screw, while the flanges facing away from the working direction of the cutting tool kenflächen act only when releasing the clamping and in the opposite direction as an extension screw. When the tool is clamped, it is only held in the respective receptacle via the remaining parts of the conical surface, only axial tightening forces that occur, for example when milling, will be additionally safe from the thread flanks acting in the pulling direction supported. In addition, the torsional forces that occur during work are mainly supported via the worm-like thread flanks and in connection with the cone seat in a totally non-rotatable manner.

In order that tapered fitting threads can be produced more easily by rolling, only a small thread depth is provided, and in a further embodiment it can also be provided that in the case of web ribs or grooves produced by rolling, each has at least one of the flank surfaces of the groove or web rib to create a depression or a free space for the material displaced by the rolling from the counterpart.

If the cutting tool, especially for smaller tool diameter, made of hard or hardened material can be provided according to another feature of the invention that only the tool is equipped with a conical fitting thread and the exception associated with the cutting tool made of softer material only has a corresponding smooth-surface cone recess, such that when the first cutting tool is inserted, the conical receptacle, which consists of a less hard material, is automatically provided with a profile.

Since a connection of both the tool with the clamping part or the extension and the clamping part with the clamping sleeve via mutual conical engagement makes it difficult or impossible to loosen the respective connection without the aid of an aid, the invention further provides that a wrench size is formed on at least one of two parts to be connected, cutting tool and extension part or extension part and clamping part, and a lubricant is applied in particular between the clamping surfaces.

In connection with this replacement of the usual chuck of the drilling machine by a clamping sleeve, it can further be provided according to the invention that the clamping part has a groove recess in its conically shaped clamping area for receiving a ball of a bayonet lock arranged in the correspondingly designed clamping sleeve of a machine tool, in particular a drilling machine .

In an embodiment which is particularly suitable for impact drills, it is also provided that the cutting tool is received directly in the receiving sleeve directly via cones in order to achieve a further reduction in weight, as a result of which the impact force is increased again.

Finally, in the event of a possible breakage of the tool, the removal of the part of the hole remaining in the borehole

^ SAT Problems associated with the drilling tool are largely excluded, and it should also be provided that a predetermined breaking point, in particular a shear groove, is arranged in the shank of the cutting tool between its working part and its clamping part, in such a way that the drill is in any case not located within the borehole Point breaks and is therefore easier and easier to remove from the borehole with simple means.

It should be noted that the clamping system of the invention through continuous connection above in its various embodiments for the sake of clarity in Ver¬ with the application example of a rotatable and rundlaufsi- Cheren connection of tool parts ^"has been explained, but he find basically a general-purpose clamping system for connecting parts of all kinds and for use in all areas.

The invention is described in detail in the following description of examples with reference to some exemplary embodiments shown in the drawing. In the drawing, the

1 shows a longitudinal section through a tool for producing threaded bores in the full material in a tool holder equipped with a concentricity adjustment facility;

Figure 2 is a plan view of the tool of Figure 1;

FIG. 3 shows a partial longitudinal section through a bayonet lock;

4 shows a section through the bayonet lock according to Figure 3 along the line IV-IV;

Figure 5 is a partial side view of the bayonet lock of Figures 3 and 4;

ER _S A _T ZBLATT FIG. 6 shows a section through a further design form of a bayonet locking device;

FIG. 7 shows a cross-sectional illustration of the bayonet lock according to FIG. 6;

FIG. 8 shows a detail of a bayonet lock on a type of reducing sleeve with a tensioning slot running in two directions.

FIG. 9 shows a two-part tool shank inserted into a clamping sleeve with countersink inserted therein;

FIG. 10 shows a two-line tool shank inserted into a clamping sleeve with milling cutters inserted therein;

FIG. 11 shows a two-part tool shank inserted into a clamping sleeve with a smaller diameter drill inserted therein;

FIG. 12 shows a two-part tool shank with long drills of larger diameter inserted therein;

FIG. 13 shows a large diameter long drill bit inserted into a receiving sleeve by means of a bayonet lock;

FIG. 14 shows a drill with a smaller diameter received via a multi-part tool shank;

FIG. 15 a countersink for larger diameters received via a multi-part tool sheep;

FIG. 16 a long carbide drill bit and holder in a clamping sleeve}

REPLACEMENT LEAF FIG. 17 shows a variant of the clamping for a rock drill in a conventional impact-resistant quick-action chuck;

FIG. 18 another variant of the clamping for a rock drill in a receiving sleeve;

FIG. 19 a further variant of the clamping for a rock drill clamped directly in the receptacle and receiving sleeve with an inner cone;

FIG. 20 shows a further variant of the clamping for a rock drill and receiving sleeve with an inner cone;

FIG. 21 shows a further variant of the arrangement for clamping a stone drill and receiving sleeve with an inner cone;

FIG. 22 shows the connection between the tool and the clamping sleeve on an enlarged scale or a connection of larger tools;

FIG. 23 shows another embodiment of the connection between the tool and the clamping sleeve, also on an enlarged scale or a connection of larger tools.

A basic holder 5 is clamped in a milling cutter holder 4, which is provided with a concentricity adjustment device formed by inclined screw bolts i and support surfaces 3 arranged on a tool holder 2. A milling cutter extension 6 is clamped in the basic holder 5, in which a face milling cutter 7 is clamped in turn. the face milling cutter 7 has a milling cutter head 8 and a milling cutter shaft 9 and is free of play in a correspondingly conical slot over the milling cutter shaft 9 which tapers conically towards its free end Receiving recess 10 of the cutter extension 6 added. The milling head is equipped on its working side with flank cutting edges 11 and cutting edges 12 and 13, with a number of cutting edges 12 being designed as V-cutting edges and a corresponding number of cutting edges 13 as simple cutting edges, and with simple cutting edges 13 and V-cutting edges 12 in the circumferential direction are arranged alternately in succession, as can be seen in particular from the illustration in FIG. Following the cutter head 8, a threading device, formed by an annular body 15 equipped with a cutting ring 14, with radially oriented threading teeth is placed on the cutter shaft 9. The ring body 15 has an inner surface 16 which is conical to the taper of the cutter shank 9. For a rotationally secure connection to the cutter head 8, the ring body 15 is provided on its lower string side with an axial recess 17, which has a square profile cross section and into which an axial extension 18 arranged on the rear side of the cutter head 8 engages, the axial extension 18 for Forming a wrench size also has a square profile cross-section, and the clear width of the axial recess 17 in the annular body 15 is greater by an amount than the profile cross-section of the axial extension 18 on the milling cutter head 8 that the latter just barely touches one Slipping in the recess 17 is prevented. This results in a wedging of the edges of the axial extension 18 on the peripheral surfaces of the axial recess 17 in the ring body 15 during operation of the tool, with the result of an absolutely play-free bracing of the end mill 7 and the cutting ring 14. Furthermore, the milling cutter head 8 is in the area of its provided at the top with an inwardly inclined circumferential bevel 19. A ring 20 made of a resiliently elastic material is arranged between the lower end face of the milling cutter extension 6 and the upper end face of the ring body 15. On its outer circumference, the ring body 15 is also provided with a wrench size 21, just as the milling cutter extension 6 is provided with a wrench size 22 on its outer circumference. The end mill 7

A is provided with an axial recess 23 penetrating its shaft 9 and its head 8, to which corresponding axial bore recesses 24, 25 and 26 in the milling cutter extension 6, in the basic holder 5 and in the tool holder 4 are aligned.

The end mill 7, together with the ring body 15 placed on its head 8, is fixed in the axial direction and in a rotationally secure manner via its conical milling cutter shaft 9, which is accommodated in the conical receiving recess 27 without play. In the exemplary embodiment shown, the bayonet lock consists of a ball 27, which is accommodated in the wall of the milling cutter extension 6 over the major part, approximately 60% of its circumference, and a ball 27 arranged in the peripheral surface of the milling cutter shaft 9, starting from the milling cutter head 8, rising helically and at the top a circumferential groove 28 extending transversely to the milling cutter axis. As a result, the face milling cutter 7 can be screwed into the milling cutter extension either by itself or together with the ring body 15 which carries the cutting ring 14 and locked therein, and locked at the same time. In order to facilitate the loosening of the end mill 7 alone or together with the ring body 15, it is initially provided that the cutter shaft 9 is provided with a coating of lubricant and that both the cutter extension 6 and the cutter head 8 or the ring ¬ body 15 are each provided with a wrench size 18 or 21 and 22.

The base holder 5 is equipped on the underside with countersink cutting edges 30 formed in the exemplary embodiment shown by turning plates 29. The cutter extension 6, which is conically formed in its upper region 31, is received at least almost free of play in a conically shaped receiving bore 32 of the basic holder 5 and is locked by means of a bayonet lock, the bayonet locking two in the wall for the most part of its circumference of the basic holder 5 includes balls 33 and two grooves 34 arranged in the outer circumferential surface of the region 31 of the milling cutter extension 6 and rising upwards in a helical manner. Likewise ^" , the basic holder 5 is locked in the tool holder 2 by means of three balls 37, which are received for the most part in their circumference in recesses in the wall 35 of the tool holder 2 and engage in circumferential grooves 36 of the basic holder 5, although the grooves 36 are arranged starting from the upper end of the basic holder 5.

In the embodiment of a bayonet lock shown in FIGS. 3 to 5, a driven part 40 is received without play via a conically shaped end region 41 in a receiving recess 42 of a driving part 43 which is conical in shape and the bayonet lock is predominantly by a number of its own Balls 46 received in the wall 44 of the driving part 43 and engaging in associated grooves 45 in the driven part are formed. In this case, the grooves 45 are arranged starting from the upper end of the driven part 40 in a straight line, running obliquely downward, and are provided at their lower end with a pocket 47 oriented transversely to the axis of the driven part. The pocket 47 is oriented with respect to its longitudinal extent at an angle to the horizontal. As can be seen in particular from the illustration in FIG. 3, the driven part 40 can also be associated with a reverse rotation, which in the exemplary embodiment shown is arranged by a number of screws 48 and 43 arranged tangentially to the axis of the driven part 40 in the wall 44 of the driving part 43 this associated radial contact surfaces 49 is formed on the driven part 40. By adjusting the screw axes and the radial support surfaces about 30 ° in addition to an anti-rotation lock, a support effect or tensioning effect can be achieved at the same time.

Finally, FIGS. 6 and 7 show yet another

REPLACEMENT LEAF Shown for a bayonet lock, in which bolts 50 are used instead of balls, which bear over correspondingly larger flank surfaces 51 with a correspondingly lower surface pressure on the recesses in the wall of the driving part and equally also in the groove recess of the driven part . ,

FIG. 8 shows a reducing sleeve 60 designed in the manner of a cut drill chuck, which has a radial groove recess 61 which extends from top to bottom and then has two end regions 62 and 63 of the groove recess 61 which extend in opposite directions and which Art that the clamping and, accordingly, the release can take place in one or the other direction of rotation. The two end regions 62 and 63 of the radial groove recess are aligned at a flat angle to the horizontal.

In the embodiments shown in FIGS. 9 to 17, the cutting tool is a drill, the cutting tool shown in FIG. 1 being a centering drill 1, which has an outer cone 2 on each side of a central section 111, such that the centering drill 1 can be used on both sides by turning. In the exemplary embodiment shown, the center drill 1 is received via its one outer cone in the inner cone 3 of an extension 4. The extension 4 is in turn received in a clamping sleeve 5 via an outer cone 222 and an inner cone 333 and a bayonet lock 8, 9 in a rotationally and concentrically secure manner. On the other hand, the clamping sleeve is provided with an internal thread 10, by means of which it can be connected to an output spindle of the drilling machine, which is not particularly shown in the drawing.

In the embodiments according to FIGS. 10 to 12, the cutting tool 1, which is designed as a milling cutter or a drill, is fixed in the extension 4 by a conical fitting thread 11, 12, while the extension 4 is fixed by a ball 8 and an insertion slot 9 formed Bajo¬ nice closure is fixed in the clamping sleeve 5.

ERS ^A TZBLATT In the embodiment according to FIG. 13, the cutting tool 1 is the longest tool to be clamped and is fixed directly in the clamping sleeve 5 by means of the cones 2,5 and a bayonet lock 8,9.

In the embodiment shown in FIG. 14, the cutting tool 1 is received once by a conical fitting thread 11, 12 in a first extension 13, which in turn is fixed in a second extension 14 via a conical fitting thread 11, 12, the second extension 14 by means of a cone pair 2, 3 and a bayonet lock 8, 9 is accommodated in the clamping sleeve 5 and is secured against rotation and rotation.

In the exemplary embodiment shown in FIG. 15, the cutting tool 1 is received in a first extension 15 via a conical fitting thread 11, 12 in a rotationally and rotationally secure manner, while the extension 15 in a second extension 16 via a smooth surface cone pairing 222, 533 and a bayonet ¬ nice locking 8, 9 is added. The second extension 16 is in turn also received via a smooth-surface cone pairing 222, 335 and a bayonet locking device 8, 9 in the clamping sleeve 5 in a rotationally and rotationally secure manner. In the exemplary embodiment shown in FIG. 16, the cutting tool 1 is designed as a rock drill and is extended exclusively via smooth-surface cones 222, 333 and these in the clamping sleeve 5 also smooth-surface cones 222, 353 and additionally via a bayonet lock 8, 9 concentric and rotationally fixed.

FIG. 9 shows a cutting tool 18 designed as a rock drill, which is clamped in by means of a quick-action chuck 17 that is usual for impact drills, the quick-action chuck being connected to the output spindle 19 of the hand drill 20 via an internal thread 10.

In the exemplary embodiment shown in FIG. 17, a rock drill 18 is received by means of an extension 4 in a clamping sleeve 5, the rock drill 18 in the extension 4 via smooth-surface cones 222, 335 and these

REPLACEMENT LEAF for its part is accommodated in the clamping sleeve 5 by means of smooth-surface cones 222, 333 and a bayonet lock 8.9 in a rotationally and rotationally secure manner. The clamping sleeve 5 is in turn connected to the output spindle 19 of the hand drill 20 via an internal thread 10.

FIG. 18 shows a hand drill 20 whose output spindle 19 is provided with an external thread 21, to which an internal thread 10 of the clamping sleeve 5 is assigned. The cutting tool 18, which is designed as a rock drill, is accommodated in the clamping sleeve 5 by means of a smooth cone pairing 222, 333 in a manner that it is true to rotation and secure against rotation.

FIG. 19 shows a hand drill 20, to the output spindle 19 of which a clamping sleeve 5 is connected by means of a smooth cone pairing 222, 333, in which the cutting tool designed as a rock drill 18 is in turn fixed via a further smooth cone pairing 222, 333 .

FIG. 20 shows an embodiment in which a drill sleeve 22 has a smooth inner cone 5 and a first extension 23 has a smooth outer cone 2, and drill sleeve 22 and the clamping sleeve 23 are additionally connected in a rotationally and concentric manner via a bayonet lock 8, 9 . The cutting tool 1 is received in a second extension 4 by means of a fitting thread 11, 12, the second extension being received in the first extension 23 by means of a smooth cone pairing 222, 353 and a bayonet lock 8, 9.

The cutting tool 1, which is designed as a steel drill, is provided with a shear groove 24 which forms a predetermined breaking point. Furthermore, the two extensions are each provided with a key width 25.

FIGS. 21 ^' and 22 show two embodiments of conical fitting threads, FIG. 22 showing an embodiment in which the conical outer surfaces of the conical end region 222 of the cutting tool 1 and the conical end region recess 353 of the extension 4 or of the receptacle a s groove-shaped circumferential groove recess

E _RSA TZBLATT _ ~ 9 _

30 and also a spiral-like, all-round web

31 are subdivided into helically rising surfaces 32, the circumferential groove 30 on the one hand and the circumferential web rib 31 on the other hand having triangular cross-sectional shapes which are not congruent with one another and wherein in the external thread of the tool 1 there are depressions 40 for the thread-rolling process in the counterpart 4 To create material order.

In the embodiment illustrated in the Figure 23 embodiment, the Konusman¬ come telflächen 222 and 333 before and in the embodiment of Figure 22, but here is the spirally ascending circumferential Nutaunehmung 300 and the equally spiralen- förm ^'ig rising circumferential rib 510 in the tightening direction sur fa ¬ designed to be larger or flatter. It is also provided in both embodiments that the cross-sectional shapes of the grooves 30 or 300 and the web ribs 31 are respectively ^"310 such von¬ designed deviating each other that they direction in a clamped cutting tool 1 in the extension 4 with their the Arbeits¬ of the cutting tool Flank surfaces 35 facing away enclose a gap-shaped free space 36 between them.

Annotation:

The conical fitting threads described here can have all conceivable thread flanks and pitches, but in order to be able to maintain the mode of action of cone connections, the cone surfaces that are used must always have the entry. Set requirements adapted to be sufficiently large.

Claims

 P A T E N T A N S P R Ü C H E:

1) Clamping system for the rotationally and concentrically secure connection of parts, in particular tool parts, such as tool and tool extension, in which a conical section of the tool shaft is received in an inner cone of the tool extension, characterized in that the tool (7) is above its conical tool ¬ shaft (9) in a correspondingly conical receiving recess (10) having a tool extension (6) can be locked by means of a bayonet lock in a rotationally and concentrically secure manner, the bayonet locking from at least one of the majority of its circumference in an interior Recess of the inner cone, in particular a tool extension (6), accommodated ball (27) and a circumferential groove arranged obliquely, in particular screw-like, rising on the outer circumference of the correspondingly conically shaped part to be clamped, in particular the tool shaft (9) (28) best and the ball (27) engages in the circumferential groove (28) with almost no play.

2) Clamping system according to claim 1, characterized in that the tool head (8) or tool shank (9) and a cutting ring (14) which can be connected to this by means of mutually arranged interlocking axial cross-sections having a cross-sectional shape deviating from the pure circular shape (18) and recesses (17) engage in one another in a rotationally secure manner and the cross-section of the shoulders (18) and the recesses (17) are dimensioned such that mutual turning is just barely ruled out and that between the end faces of the tool holder and the tool to be clamped resilient ring (20) is switched on.

3) clamping system according to claim 1 or 2, characterized in that over the outer circumference of the tool shank (9) and

REPLACEMENT LEAF The inner circumference of the receiving recess (10) of the tool extension (6) has a plurality of radial groove recesses (28) distributed in the tool shank and associated balls (27) or bolts (50) partially received in recesses in the tool extension (6) , wherein the groove recesses (28) in the tool shank (9) are arranged parallel to each other.

4) Clamping system according to claim 1 to 5, characterized in that the bayonet locking by at least one of the majority of its circumference received in a recess of the tool shank and free of play in a radial internal circumferential groove arranged obliquely or helically rising in the tool extension in the axial direction engaging ball or a bolt is formed and that the circumferential groove (61) has end regions (62, 63) which extend in opposite directions, in such a way that the tool can be clamped in both directions of rotation and that on at least one of the conically shaped mutual contact surfaces, for example of the tool shank (9) or the tool extension (6), a lubricant is applied.

5) Clamping system according to one or more of the preceding claims 1 to 4 and also for general use that in the connection of all rotary parts (40) and also in the connection of all non-rotary parts e.g. In the connection between a tool, a tool extension or a tool holder with the driving part (43), a bayonet lock (45 to 47) according to one of the preceding claims is switched on, the connection of an internal cable path, e.g. a pipe path (26, 25, 24 and 23) forming pipeline or tool parts a bayonet lock (27/28, 33/34, 36/37, 45/46 or 50/51) is switched on.

ER _S ATZBLATT 6) Clamping system according to one or more of the preceding claims 1 to 5, characterized in that between the driving (43) and the driven part (40) one arranged tangentially in the wall (44) of the receiving driving part (43) and with Corresponding radial surfaces (49) on the driven part (40) interacting screws (48), at the same time forming an anti-rotation device, are provided, the screws (48) and the radial surfaces (49) corresponding to the required tension up to Are set at 30 °.

7) Clamping system according to one or more of the preceding claims 1 to 6, characterized in that the clamping of the cutting tools (1 and 18) via cones (2 and 3 or 222 and 333) and via a conical fitting thread (11 u.19) and the tool (1) (centering drill) can be clamped to the fold over the cones (2), the conical outer surfaces (222) of the conical end region of the cutting tool (1) and the conical end region recess (533) of the clamping sleeve (4) by a spiral groove recess (30) that rises in a spiral and the like

A spiral-extending web (51) is divided into helically rising conical surfaces (32), the circumferential groove (30) on the one hand and the circumferential web rib (31) on the other hand having non-congruent triangular cross-sectional shapes such that they Surfaces together form a conical fitting thread (11 and 12).

8) Clamping system according to claim 7, characterized in that the cross-sectional shapes of the grooves (30) and the web ribs (31) are designed so that they differ from each other in such a way that when the cutting tool (1) is clamped in the extension (4) with the working direction of the tool facing away flank surfaces enclose a gap-shaped free space (36) and that in the case of those produced by rolling

ERSA _T ZBLATT Web ribs (31) or grooves (30) each create a depression (40) or a free space next to at least one of the flank surfaces of the groove or web rib in order to be able to receive the material displaced by the rolling process from the counterpart, and furthermore A predetermined breaking point, in particular a shear groove (24), is arranged in the shank of the cutting tool (1) between its working part and its clamping part.

9) Clamping system according to claim 7 and 8, characterized in that the cutting tool (1) or the extension (4) is accommodated in a sleeve (5) arranged in place of the known chuck (17), which sleeve (5) with the work spindle (19) the machine (20) via an internal thread (10) or an internal or. Outer cone (333 and 222) can be connected and, on its tool-receiving side, has an inner cone (333), optionally provided with an additional bayonet lock (8 and 9), and that almost all parts have a wrench size (25) and that this is independent of the respective axial length of the cutting tool (1), cutting tool (1) and tool extensions (4 and 13 to 16) together always always have an at least approximately constant overall length.

ERSA _T ZBLATT