EP0463344A2 - Chucking device with power assist, especially machine vice - Google Patents

Abstract

A machine vice with a power amplifier has a fixed jaw (2) and a movable jaw (3) on a vice body (1, 1a, 1b), which can be adjusted by means of a screw spindle (14). The power amplifier (9, 10, 11) is enclosed by a rotatable clamping sleeve (6) which engages with an external thread (7) in a nut thread (6) of a housing (5) surrounding it. A first clamping ring (9) is arranged in the clamping sleeve (6) in a rotationally fixed manner and a second clamping ring (10) can be rotated to a limited extent. Several clamping bolts are provided between the two clamping rings (9, 10). The stationary housing (5) is arranged in the vice body (1, 1a) under the fixed jaw (2). The second clamping ring (10) is fixedly connected to one end (13a) of a pull rod (13) extending through the first clamping ring (9) and the screw spindle (14), at the other end (13a) there is an adjusting sleeve (21) and engage an operating lever (15). Disc springs (23) and at least part of the adjusting sleeve (21) are arranged in a handle (25) of the screw spindle (14) and are supported on the bottom (25a) of the handle (25) with the interposition of an axial bearing (24).

Description

The invention relates to a clamping device with a power amplifier, in particular a machine vice, with a clamping device body, a fixed jaw arranged thereon and a jaw movable relative to it, for the adjustment of which a rod which can be acted upon by the power amplifier is provided, with a rotatable clamping sleeve surrounding the power amplifier , which has an external thread and engages with it in a nut thread of a stationary housing surrounding it and whose rotational movement with respect to the housing is limited by stop faces, with a first clamping ring arranged in a rotationally fixed manner in the clamping sleeve, with a second clamping ring arranged in the clamping sleeve so as to be rotatably limited is rotatable by means of an actuating lever for the power amplifier, with a plurality of clamping bolts arranged between the clamping rings, which in an end position (open position) of the second clamping ring are inclined at an acute angle to the axis of the clamping sleeve and in the other end position (clamping position) of the second clamping ring are arranged approximately parallel to the axis of the clamping sleeve, with a compression spring acting on the second clamping ring in the direction of the first clamping ring and with an axial bearing and several disc springs arranged in the area of the handle, the pretensioning of which by an adjusting sleeve is adjustable, which can be further tensioned by means of the power amplifier and act on the rod in the tensioned position of the second tensioning ring.

In a clamping device of this type (DE 37 29 093 C1), the stationary housing surrounding the clamping sleeve is arranged axially outside a stationary part of the clamping device. The adapter sleeve and about half of the power amplifier protrude axially from the housing. This is followed in the axial direction by the plate springs and the adjusting sleeve, which in turn can be screwed onto the clamping sleeve. The handle of the screw spindle also protrudes from the adapter sleeve. Overall, the overall length of the device in relation to its maximum span is quite large due to the axial arrangement of the components mentioned in connection with a stationary part of the device body. The parts of the drive and the power amplifier that protrude relatively far beyond the device body are also exposed to the risk of damage. Finally, the movable jaw is pressed against the workpiece by a push rod that is adjustable in the hollow screw spindle. The clamping forces generated in this way result in forces on the fixed jaw and the stationary part of the device body which are directed in opposite directions to one another and which can lead to a deflection of the device body in its central part upwards. The latter has the result that the jaws no longer run exactly parallel to one another, but have a greater distance in the upper region than in the lower region. As a result, the workpiece is only clamped in the lower area of the jaws. However, the known clamping device described above has the advantage that, thanks to the screwable clamping sleeve and the power amplifier arranged in it, with a relatively small total rotation angle of the actuating lever of less than 180 °, an opening and clamping stroke of the movable jaw of approximately 2-4 mm and thus a so-called Quick clamping with power amplification is possible.

In contrast, the invention has for its object to provide a clamping device with a power amplifier, in particular a machine vise of the type mentioned, while maintaining the quick clamping, in which the ratio of the maximum span to the overall length is optimally large, as well as deformations of the device body by the clamping forces should be avoided if possible.

This is achieved according to the invention in that the stationary housing is arranged in the device body under the fixed jaw or is formed in the area located under the fixed jaw in that the second clamping ring with one end extends through the first clamping ring and the movable one Cheek extending tie rod is fixedly connected, with the other, from the movable jaw out the end connected to the adjusting sleeve and the actuating lever can be connected, and that the plate springs are arranged and are supported with the interposition of the axial bearing on the side of the movable jaw facing away from the fixed jaw.

The arrangement of the stationary housing, the clamping sleeve and the power amplifier in the area under the fixed jaw results in a particularly short design of the clamping device, because all components essential for generating high-pressure clamping are components that determine the overall length of the clamping device integrated into it. The ratio of the maximum span to the overall length is thus optimally large. The sensitive parts of the clamping device, such as the clamping sleeve and the power amplifier itself, are protected in the area under the fixed jaw. The disc springs, the axial bearing and the adjusting sleeve can also be arranged, if necessary, protected within a hollow handle of a screw spindle. This largely eliminates the risk of damage. The pull rod has a dual function in the new tensioning device. It serves on the one hand to drive the clamping sleeve and the power amplifier and on the other hand it transmits the clamping force from the power amplifier arranged at one end of the clamping device to the adjusting sleeve arranged at the other end and via the plate springs supported on it, the axial bearing and, if applicable, a screw spindle to the movable jaw . By means of the drawbar, the clamping force is transferred directly to the movable jaw as a tensile force when clamping a workpiece, so that the device body itself is largely relieved of clamping forces and deformations and the associated disadvantages cannot occur.

From DE-GM 87 17 051 a machine vice with drive by a threaded spindle is known in which the clamping force by the arrangement of the spindle abutment in the area below the fixed vice jaw and the spindle nut on a slide carrying the movable jaw when clamping a workpiece by means of the threaded spindle is transmitted as a tensile force directly to the movable jaw, so that the vice body itself is largely relieved of clamping forces and deformations of the vice body and the associated disadvantages cannot occur. However, this vice is clamped by rotating an ordinary threaded spindle without rapid clamping with a small overall angle of rotation under power amplification.

The subclaims provide further advantageous refinements of the invention under protection.

• Fig. 1 einen Längsschnitt eines ersten Ausführungsbeispieles in Form eines Maschinenschraubstockes,
• Fig. 2 einen Teillängsschnitt einer zweiten Ausführungsform ebenfalls in Form eines Maschinenschraubstockes,
• Fig. 3 einen Querschnitt nach der Linie III-III der Fig. 1.

The invention is explained in more detail below with reference to exemplary embodiments shown in the drawing. It shows

• Fig. 1 a longitudinal section of a first embodiment in the form of a machine vice,
• Fig. 2 shows a partial longitudinal section of a second embodiment also in the form of a machine vice,
• Fig. 3 is a cross section along the line III-III in FIG. 1.

The vice body 1 in the embodiment shown consists of a head part 1 a, which is screwed to a guide part 1 b. However, the head part and the guide part can also consist of one piece. The head part 1 a carries in its upper region a fixed jaw 2 , which can also be detached from the head part in a known manner. In the guide part 1 b, the movable jaw 3 is slidably mounted on longitudinal guides, not shown. Here, too, the movable jaw can be detachable from a slide carrying it, but this is not shown in the drawing for the sake of simplicity. In the head part 1 a of the vise body, a housing 5 is arranged in a corresponding recess 4 under the fixed jaw 2 in a rotationally fixed and axially immovable manner, ie rigidly connected to the head part 1 a. The housing 5 could possibly also consist of one piece with the head part 1 a. In the housing 5 , an adapter sleeve 6 is rotatably supported to a limited extent. The clamping sleeve 6 has an external thread 7 , which engages in a corresponding nut thread 8 of the housing 5 . The two threads 7 , 8 are expediently designed as coarse threads (steep threads). In the exemplary embodiment shown, the external thread 7 is a trapezoidal thread Tr 50 × 10 (mm), ie it has a pitch or pitch of 10 mm with a nominal diameter of 50 mm. Since the pitch of the external thread 7 is essential for the infeed or opening stroke that can be achieved with a predetermined angle of rotation of an operating lever described below, and since the external thread 7 must always have self-locking, the pitch cannot be increased arbitrarily. For this reason, it is advantageous if the external thread has a nominal diameter of at least 44 mm with a pitch of 8 mm.

A first clamping ring 9 is arranged within the clamping sleeve 6 and is firmly connected to the clamping sleeve. The first clamping ring 9 and the clamping sleeve 6 can also consist of one part, as shown. The clamping ring 9 forms a first part of a power amplifier enclosed by the clamping sleeve 6 . A second clamping ring 10 is arranged at a distance from the first clamping ring 9 in the clamping sleeve 6 to a limited extent and axially displaceably. Between the two clamping rings 9 , 10 a total of three clamping bolts 11 are provided, each offset by 120 ° in the circumferential direction. In one end position of the second clamping ring 10 , which corresponds to the relaxed open position of the machine vise, the clamping bolts 11 assume an acute angle μ of, for example, 10 ° with respect to the axis A of the clamping sleeve 6 , as is indicated in FIG. 1 by dash-dotted lines.

With the clamping ring 10 , one end 13 a of a pull rod 13 is fixedly connected via a cross bolt 12 , which extends through the other clamping ring 9 and a hollow screw 14 and with its other end 13 b is led out of the screw spindle 14 . At this other end 13 b of the pull rod 13 , the operating lever 15 shown in dash-dotted lines can be used, with which the pull rod and thus also the second clamping ring 10 can be rotated. A stop pin 16 is arranged in a semi-cylindrical recess of the second clamping ring 10 . The clamping sleeve 6 has a first recess 17 , the end surfaces 17 a and 17 b of which form stop surfaces for the stop bolt 16 . In the one end position of the clamping ring 10 , which corresponds to the relaxed open position of the machine vice, the stop pin 16 bears against the stop surface 17 b. The other end position of the second clamping ring 10 is determined by the stop surface 17 a, against which the stop bolt 16 rests in the clamping position of the machine vice. When pivoting the second clamping ring 10 from the open position into the clamping position, the ends of the clamping bolts 11 engaging in the clamping ring 10 are taken along, so that the angle μ between the clamping bolt axes a and the clamping sleeve axis A is reduced and shortly before reaching the clamping position it becomes 0 °. The stop surface 17 a is arranged so that the clamping bolts 11 in the clamping position of the clamping ring 10 are always slightly moved over their parallel position to the clamping sleeve axis A, ie beyond their dead center position, whereby a secure locking of the power amplifier is achieved.

On the end protruding from the screw spindle 13 b of the pull rod 13 , a bushing 18 is arranged, which is connected by means of a transverse pin 19 in a torque-proof and rotationally fixed manner to the end 13 b. The cross pin 19 penetrates the sleeve 18 and the tie rod end 13 b and is held by means of a spring-loaded locking ball 20 . In this way, the bush can be easily released by pulling out the cross pin 19 from the pull rod 13 if necessary. The actuating lever 15 also acts on the transverse pin 19 . On the sleeve 18 , an adjusting sleeve 21 is axially adjustable by means of a fine thread 22 . With this adjusting sleeve 21 , the biasing force of several plate springs 23 can be adjusted. The plate springs 23 act in the tensioned position via an axial bearing 24 on the bottom 25 a of a high handle 25 . The bottom 25 a is connected to the end 14 a of the screw spindle 14 opposite the fixed clamping jaw 2 . The hollow handle encloses the thrust bearing 24 , the plate springs 23 and part of the adjusting sleeve 21 . The spindle 14 can be rotated by means of the handle 25 and the movable jaw 3 can thus be adjusted relative to the fixed jaw 2 . By turning the adjusting sleeve 21 relative to the bush 18 , the force of the plate spring assembly 23 and thus the clamping force that can be achieved with the machine vice can be adjusted.

Since the biasing force generated by the plate springs 23 is relatively large, it would impede the rotation of the screw spindle 14 for the rough adjustment of the jaw 3 despite the axial bearing 24 . For this reason, the bushing 18 has an annular shoulder 26 adjacent to its part 18 a which supports the plate spring, to which a shoulder 27 adjoins, on which the axial bearing 24 is arranged. The diameter of the shoulder 27 is larger than the part 18 a carrying the plate springs. Following the shoulder 27 , a flange 28 is provided which is axially displaceable in a recess in the bottom 25 a. The axial distance between the annular shoulder 26 and the flange 28 is the same or somewhat greater than the axial width of the thrust bearing 24 . In this way, the plate springs 23 do not rest against the axial bearing 24 or only with very little force in the relaxed position of the machine vice and thus do not hinder the rotation of the screw spindle 14 in any way. Between the fixed jaw 2 facing end 14 b of the screw spindle 14 and the head part 1 a of the vice body 1 , a compression spring 30 is arranged, which surrounds the tie rod 13 concentrically. This compression spring 30 presses the hollow spindle 14 to the right in the open position of the machine vice and also ensures that the clamping bolts 11 remain in their oblique position relative to the clamping sleeve axis A during the feed stroke.

So that the actuating lever 15 always moves within a predetermined angular range when clamping and opening the machine vice, which is essential for quick clamping, the rotational movement of the clamping sleeve 6 relative to the housing 2 in the opening direction is by a second stop pin 31 and a stop surface interacting with it 32 a limited, which is an end face of a recess 32 provided in the clamping sleeve 6 . The stop pin 31 is fixed in a semi-cylindrical recess in the housing 5 . An additional torsion spring 34 between the two clamping rings 9, 10 together with the stop bolts 16, 31 and the stop surfaces 17 b and 32 a ensures a defined starting position of the actuating lever 15 before each clamping operation.

The housing 5 is sealed by means of a cover 33 and filled with oil or grease, so that parts of the tensioning device and the power amplifier contained therein are insensitive and durable even under extreme operating conditions.

The mode of action is as follows:
For rough adjustment of the span of the machine vise, the hollow spindle 14 is rotated by means of the handle 25 . Due to their in the spindle nut 3 a of the movable jaw 3 engaging threads, the movable jaw is moved. The span of the machine vice can thus be infinitely adjusted. In practice, the span is set approx. 2 mm larger than the dimension of the workpiece to be clamped so that it can be inserted into the machine vice unhindered.

The workpiece is then clamped and unclamped (quick clamped) by means of the separate actuating lever 15 . In the open position of the machine vice, the clamping sleeve according to FIG. 3 is rotated so far to the right that the stop surface 32 a rests on the stop bolt 31 . In addition, the second clamping ring 10 is rotated so far to the right that the stop pin 16 abuts the stop surface 17 b. The actuating lever then assumes the position shown in broken lines in FIG. 3. By pivoting the operating lever 15 shown in FIG. 3 to the left in the counterclockwise direction, the pull rod 13 and thus also the second tightening ring 10 is rotated. Under the action of the compression spring 30 and the torsion spring 34 , the clamping bolts 11 initially remain in their oblique position with respect to the clamping sleeve axis A. During the initial rotation of the second clamping ring 10 , the first clamping ring 9 is thus also carried in the same direction of rotation. Since this is rotationally fixedly connected to the clamping sleeve 6, and the clamping sleeve 6 is first rotated in the same rotational direction. By the interaction of the external thread 7 with the nut thread 8 , the clamping sleeve 6 moves to the left according to FIG. 1. About the first clamping ring 9 and the clamping bolt 11 , the second clamping ring 10 is moved to the left and takes on the tie rod 13 , the bush 18 , the plate springs 23 , the thrust bearing 24 and your bottom 25 a with the screw 14 , which in turn the movable Jaw 3 moved in contact with the workpiece. The path that the movable jaw 3 travels from its open position to its contact with the workpiece is referred to as the feed stroke. If this feed stroke is 2 mm, for example, the actuating lever 15 must be pivoted by an angle β of 72 ° according to FIG. 3.

As soon as the jaw 3 rests on the workpiece, the torque increases and a further rotation of the clamping sleeve 6 is blocked by the threads 7, 8. The first clamping ring 9 cannot turn any further. now the actual clamping stroke takes place. When the second clamping ring 10 is rotated further to the left according to FIG. 3, the clamping bolts 11 are erected, ie the angle μ with respect to the clamping sleeve axis A decreases. This erection of the clamping bolts 11 increases the distance between the two clamping rings 9 , 10. The rotation of the second clamping ring 10 is continued until the axes a of the clamping bolts 11 are opposite by about 3 ° beyond their dead center position running parallel to the clamping sleeve axis A. are inclined to their starting position with respect to the clamping sleeve axis A. In this clamping position, the stop pin 16 then bears against the stop surface 17 a of the clamping sleeve 6 . This ensures a stable clamping position. By increasing the distance between the two clamping rings 9 , 10 during the clamping stroke by approximately 0.44 mm, the second clamping ring 10 is shifted a little more to the left and thus also moves the pull rod 13 to the left by the same amount. As a result, the plate springs 23 press with their preset clamping force via the axial bearing 24 onto the bottom 25 a and thus onto the screw spindle 14 . This presses the movable jaw 3 against the workpiece with the preset clamping force. In the event of the workpiece possibly yielding, the elasticity of the plate springs 23 maintains the clamping force, even though it drops somewhat.

The relaxation takes place in the reverse order in that the actuating lever 15 according to FIG. 3 is pivoted to the right in the opposite direction of rotation. Here, the second clamping ring 10 also rotates to the right until the stop pin 16 b on the stop surface 17 comes to rest, thereby ensuring that the clamping bolts 11 is not tilted about the intended inclination of 10 ° relative to the clamping sleeve axis A. The compression spring 30 holds the second clamping ring 10 in constant contact with the clamping bolt 11 and also causes the screw spindle 14 to be moved to the right in the open position. As soon as the stop pin 16 bears against the stop 17 b, the clamping sleeve 6 is rotated clockwise according to FIG. 3 until its stop surface 32 a comes into contact with the stop pin 31 . The actuating lever 15 thus again assumes its position shown in broken lines in FIG. 3. By rotating the clamping sleeve 6 relative to the housing 5 , the clamping sleeve according to FIG. 1 moves to the right and the screw spindle 14 can follow under the action of the compression spring 30 . The movable jaw 3 is hereby completely moved into its open position.

In the embodiment shown in Fig. 1 can be removed by pulling the cross pin 19, the bushing 18 from the pull rod 13 without affecting the bias of the plate springs 12 set by means of the adjusting sleeve 21 . After dissolution of the sleeve 18 can the screw spindle 14 together with the movable jaw 3 from the guide member 1 b for cleaning and other purposes, for example, for clamping the vice, easily removed.

The exemplary embodiment shown in FIG. 2 differs only in the connection of the adjusting sleeve 21 to the pull rod 13 . The same reference numerals are used in Fig. 2 for parts with the same function as in Fig. 1, so that a repeated description of these parts is unnecessary. In the embodiment shown in FIG. 2, the adjusting sleeve 21 , the plate springs 23 and the thrust bearing 24 are arranged directly on the end 13 b of the pull rod 13 . The adjusting sleeve 21 is adjustable by means of a fine thread 22 relative to the pull rod 13 . The pull rod has, adjacent to its part 35 carrying the plate springs 23, an annular shoulder 36 , on which see the plate springs as long as the power amplifier is not yet brought from its open position into its tensioned position. Following the annular shoulder 36 , the pull rod 13 has a section with a larger diameter than the supporting part 35 , on which the axial bearing 24 is arranged. The axial distance of the annular shoulder 36 from the bottom 25 a of the handle 25 is the same or slightly larger than the axial width of the axial bearing when the power amplifier is relaxed. This ensures, as in the previously described embodiment, that the strong spring force of the plate spring 23 is kept away from the thrust bearing 24 when the booster is relaxed and the screw spindle 14 can thus be easily rotated by means of the handle 25 for rough adjustment of the jaw 3 .

If the clamping device is generally designed as a clamping device with a predetermined span within the meaning of claim 1 , then the hollow screw spindle 14 is omitted. In this case, the bushing 18 lies with its flange 28 directly on the movable jaw 3 .

When quickly clamping workpieces, the angle of rotation β 1 of the actuating lever 15 should be less than 200 °, preferably less than 150 °. This is ensured in the machine vice according to the invention. A feed stroke of 4 mm can be achieved by a rotation angle β of 144 °. This angle of rotation β is then followed by angle α of 22 °, which is necessary to carry out the clamping stroke.

Claims (14)

Clamping device with power amplifier, in particular machine vise, with a clamping device body, a fixed jaw arranged thereon and a jaw movable relative to it, for the adjustment of which a rod which can be acted upon by the power amplifier is provided, with a rotatable clamping sleeve which surrounds the power amplifier and has an external thread and engages with this in a nut thread of a stationary housing surrounding it and whose rotational movement with respect to the housing is limited by stop surfaces, with a first clamping ring arranged in a rotationally fixed manner in the clamping sleeve, with a second clamping ring rotatably arranged in the clamping sleeve, which is actuated by an actuating lever for the Power amplifier is rotatable, with several clamping bolts arranged between the clamping rings, which in one end position (open position) of the second clamping ring are inclined at an acute angle to the axis of the clamping sleeve and in the other end position ( Clamping position) of the second clamping ring are arranged approximately parallel to the axis of the clamping sleeve, with a compression spring acting on the second clamping ring in the direction of the first clamping ring and with an axial bearing and several disc springs arranged in the region of the handle, the pretensioning of which can be adjusted by means of an adjusting sleeve which can be adjusted by means of the Power amplifiers can be further tensioned and act on the rod in the tensioning position of the second tensioning ring, characterized in that the stationary housing (5) is arranged in the tensioning device body ( 1 , 1 a) under the fixed jaw ( 2 ) or in that under the area of the fixed jaw ( 2 ) is formed such that the second clamping ring ( 10 ) is firmly connected to one end ( 13 a) of a pull rod ( 13 ) extending through the first clamping ring ( 9 ) and the movable jaw ( 3 ), with the other, out of the movable jaw end ( 13 a) connected to the adjusting sleeve ( 21 ) and the actuating lever ( 15 ) can be connected, and that the plate springs ( 23 ) are arranged and are supported with the interposition of the axial bearing ( 24 ) on the side of the movable jaw ( 3 ) facing away from the fixed jaw ( 2 ). Clamping device according to claim 1 , characterized in that the pull rod ( 13 ) is surrounded by a hollow screw spindle ( 14 ) which can be rotated by means of a hollow handle ( 25 ) and which can be screwed into the movable jaw ( 3 ) and that the plate springs ( 23 ) and at least a part of the adjusting sleeve ( 21 ) are arranged in the handle ( 25 ) and are arranged with the interposition of the axial bearing ( 24 ) at the end of the screw spindle ( 14 ) , or a base ( 25 a) connected to this end ( 14 a) support the handle ( 25 ). Clamping device according to claim 1 or 2, characterized in that the adjusting sleeve ( 21 ), the plate springs ( 23 ) and the axial bearing ( 24 ) are arranged on a bush ( 18 ) connected to the pull rod ( 13 ) in a tensile manner and in that the adjusting sleeve ( 21 ) is axially adjustable relative to the bush ( 18 ) by means of a fine thread ( 22 ). Clamping device according to claim 3, characterized in that the sleeve (18) by means of them, and the pull rod (13) penetrating the transverse pin (19) detachably connected to the pull rod. Clamping device according to claim 3 or 4, characterized in that the bush ( 18 ) adjacent to its part ( 18 a) carrying the plate springs ( 23 ) has an annular shoulder ( 26 ) on which the plate springs are supported, and then one opposite in diameter the load-bearing part ( 18 a) has a larger shoulder ( 27 ) on which the thrust bearing ( 24 ) is arranged and that a flange ( 28 ) is provided next to this shoulder ( 27 ), which in a recess ( 29 ) of the movable jaw ( 3 ) or the bottom ( 25 a) of the handle ( 25 ) is displaceable, the axial distance between the annular shoulder ( 26 ) and the flange ( 28 ) being equal to or slightly larger than the axial width of the axial bearing ( 24 ) . Clamping device according to claim 1 or 2, characterized in that the adjusting sleeve ( 2 1), the plate springs ( 23 ) and the axial bearing ( 24 ) are arranged on the pull rod ( 13 ) itself and that the adjusting sleeve ( 21 ) by means of a fine thread ( 22 ) is adjustable relative to the pull rod ( 13 ). Clamping device according to claim 6, characterized in that the pull rod ( 13 ) adjacent to its part ( 35 ) carrying the plate springs ( 23 ) has an annular shoulder ( 36 ) on which the plate springs ( 23 ) are supported and then one opposite in diameter the supporting part ( 35 ) has a larger section ( 37 ), which the axial bearing ( 24 ) is arranged, the axial distance of the annular shoulder ( 36 ) from the bottom ( 25 a) of the handle ( 25 ) when the power amplifier ( 9 , 10 , 11 ) is the same or slightly larger than the axial width of the thrust bearing ( 24 ). Clamping device according to claim 2, characterized in that the compression spring ( 30 ) surrounds the pull rod ( 13 ) and between the end ( 14 b) of the screw spindle ( 14 ) facing the fixed jaw ( 2 ) and the part ( 1 a) surrounding the power amplifier of the clamping device body ( 1 ) or the housing ( 5 ) is arranged. Clamping device according to claim 1, characterized in that the external thread ( 7 ) on the clamping sleeve ( 6 ) is a coarse thread. Clamping device according to claim 9, characterized in that the external thread ( 7 ) has a nominal diameter of at least 44 mm with a pitch (pitch) of at least 8 mm. Clamping device according to claim 10, characterized in that the external thread ( 7 ) is a trapezoidal thread Tr 50 × 10 (mm). Clamping device according to claim 1, characterized in that the angle of rotation (α) of the second clamping ring ( 10 ) relative to the clamping sleeve ( 6 ) is limited by stops ( 16 , 17 a, 17 b) so that the clamping bolt ( 11 ) in the clamping position of the second clamping ring ( 10 ) are always moved slightly beyond their parallel position (dead center position) to the clamping sleeve axis (A). Clamping device according to claim 12, characterized in that the angle of rotation (α) of the second clamping ring ( 10 ) relative to the clamping sleeve ( 6 ) is less than 25 °. Clamping device according to at least one of claims 1-13, characterized in that the maximum angle of rotation (β1) of the actuating lever ( 15 ) relative to the housing ( 5 ) is less than approximately 150 °.

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