US3807721A

US3807721A - Mechanical clamping device

Info

Publication number: US3807721A
Application number: US00203987A
Authority: US
Inventors: F Arnold
Original assignee: Individual
Current assignee: Individual
Priority date: 1970-12-10
Filing date: 1971-12-02
Publication date: 1974-04-30
Anticipated expiration: 1991-04-30
Also published as: GB1363697A; FR2118037A1; FR2118037B1; DE2060881C3; DE2060881A1; DE2060881B2

Abstract

A vise has a slide carrying a movable jaw. Rotatably mounted in this slide is a hollow spindle which screws in the vise body and has an extension in which is screwed a driving spindle. A push rod is slidable in the hollow spindle for transmitting force from a toggle mechanism to the slide. During rotation of the driving spindle in the clamping direction a clutch between the driving and hollow spindles is first engaged so that the slide is advanced by the screwing action of the hollow spindle. Subsequently, a tapered bolt advanced by the driving spindle exerts a wedging action on the toggle mechanism which is thereby extended and applies clamping force to the movable jaw via the push rod and the slide.

Description

United States Patent I 1 Arnold Apr. 30, 1974 MECHANICAL CLAMPING DEVICE Primary Examiner-Granville Y. Custer, Jr. [76] Inventor: Franz Arnold spatzenweg 48 Attorney, Agent, or FirmWoodhams, Blanchard and Kempten, Germany Flynn [22] Filed: Dec. 2, 1971 21 Appl. No.: 203,987 [57] ABSTRACT A vise has a slide carrying a movable jaw. Rotatably [30] Foreign Application Priority D mounted in this slide is a hollow spindle which screws D l 0 1970 G 2060881 in the vise body and has an extension in which is ermany screwed a driving spindle. A push rod is slidable in the hollow spindle for transmitting force from a toggle (gill. mechanism to the Slide. During rotation of the driving 58] d 269/228 spindle in the clamping direction a clutch between the are driving and hollow spindles is first engaged so that the slide is advanced by the screwing action of the hollow [56] References cued spindle. Subsequently, a tapered bolt advanced by the E STATES PATENTS driving spindle exerts a wedging action on the toggle 3,400,92'4 9/1968 Arnold et al .Q 269/228 mechanism which is thereby extended and applies 3,650,522 3/1972 Wermuth 269/228 l i force to h v bl j i the push rod and the slide.

12 Claims, 12 Drawing Figures PATENTl-imraao m4 SHEET 2 OF 3 INVENTOR fiWM Z 401 040 MECHANICAL CLAMPING DEVICE The invention relates to a mechanical clamping device, more especially a vise for the clamping of workpieces, the said device having a hollow spindle which is screwable in the stationary part of the vise, a push rod which is mounted in an axially displaceable manner in this spindle and which exerts the clamping pressure, a driving spindle which is axially screwable in an extension of the hollow spindle, a torque clutch connected between the driving spindle and the hollow spindle and a toggle-lever power amplifier arranged between the driving spindle and the push rod.

In the case of a previously known vise of thisconstruction (German Published Specification DAS No. 1,289,799) it has been proposed to provide, as the power amplifier, a pair of toggle levers, each of which consists of two compression members and a central roller, in which connection this pair of toggle levers cooperates with a longitudinally displaceable wedge acting against these rollers. In view, however, of the high clamping forces of 4 tons and above that can be exerted in the case of such a vise, this toggle-lever power amplifier is too highly stressed, so that, as a result of the resulting high frictional forces, seizing or jamming of this toggle-lever power amplifier occurs.

In this connection it is to be borne in mind that, in view of the confined space available for the pair of toggle levers in the extension of the hollow spindle, the pairs of toggle levers can have only comparatively small dimensions and that, for this reason too, the production and transmission of high clamping forces is not possible.

The object of the invention is to provide a vise having a toggle-lever power amplifier which can be accommodated in the confined space available in the extension of the hollow spindle and with which, despite comparatively small dimensions, veryhigh clamping forces can be achieved with low stressing of the toggle-lever system and correspondingly slight wear.

With this object in view, a mechanical clamping device, more especially a vise, of the construction initially referred to is provided in which, in accordance with the invention, the toggle-lever power amplifier consists of several pairs of toggle levers arranged concentrically with respect to the spindle axis and a tapering pressure bolt which is displaceable by the driving spindle and which has bearing-surface areas corresponding to the number of the toggle levers.

The invention will now be described by way of example with reference to a number of embodiments shown in the accompanying drawings, in which:

FIG. 1 is a partial longitudinal section through a vise having a mechanical power amplifier;

FIG. 2 is a longitudinal section through a part of this vise on a larger scale. The upper half of this longitudinal section shows the moving parts in the rest position, while the lower half shows them in the clamping position;

FIG. 2a is a fragmentary longitudinal section of part of a vise according to another embodiment;

FIG. 3 is a cross section along the line III-III in FIG.

FIG. 4 shows the top plan view of a push rod forming part of the power amplifier;

FIG. 5 is a front end view of this push rod as seen in the direction indicated by the arrow V in FIG. 4; 9

FIG. 6 is a fragmentary side elevation illustrating a further embodiment of a toggle-lever power amplifier;

FIG. 7 is a fragmentary longitudinal section showing part of FIG. 2 on a larger scale;

FIG. 8 shows a guide body in longitudinal section;

FIG. 9 shows this guide body in cross section; along the lines IXIX of FIG. 8

FIG. 10 shows a further guide body in longitudinal section;

FIG. 11 shows this further guide body in cross section.

In the drawings the reference numeral 1 indicates the base plate of a vise, which base plateis formed integrally with a stationary clamping jaw 2 and a bearing support 3 in which is screwably arranged a hollow spindle 5 having an external screw-thread 4. This hollow spindle 5 is mounted by means of a neck portion 6 in the rearward part 7 of a slide 8, the front part 10 of which is provided with a movable clamping jaw 9. The front end of a push rod 11, which is mounted for axial sliding movement in the hollow spindle 5, presses against the rear face of the front part 10 of the slide 8 As shown in detail in FIG. 2, the hollow spindle 5 has

extensions

5a, 5b, which form together with the hollow spindle a rigid assembly. Connected securely to the extension part 5b is a sleeve 12 which at the same time serves as a clutch part and in which a driving spindle 13 is screwed. The end 14 of the spindle 13 is connected securely to a head piece 15 which in its turn is connected securely to a sleeve 16 and a disc 17. A hand crank 18 is provided with a polygonal axle 19 which can be inserted into a corresponding polygonal aperture in the disc 17. For the clamping of a workpiece 20, this hand crank 18 is rotated in a clockwise direction and, for releasing the workpiece, in the counterclockwise direction. Connected between

hollow spindle

5, 5a, 5b and driving spindle 13 is a torque clutch. In the case of the embodiment illustrated in FIG. 2, to

, this end a dog clutch is provided, which consists of the clamped. As is clear fromthe drawings, this power amclutch disc 22 provided with dogs 21 which are engageable in corresponding recesses in the sleeve 12. The clutch disc 22 is movable in a longitudinal direction on the extension 23 of the operating spindle, however, is secured on the spindle '23 against-rotation. A disc 24 is connected to the extension 23' of the driving spindle l3. Arranged between this disc and the clutch disc 22 is a compression spring 25 which, at the beginning of the clamping operation, i.e. upon the rotation of the driving spindle 13, initially keeps the clutch members 22, 12 in engagement, so that on rotation of the driving spindle 13 the hollow spindle 5 5a, 5b is simultaneously rotated and is screwed into the internal screwthread of the bearing support 3. Thus, the slide 8 is advanced to the workpiece 20 by means of the push rod 11 which is displaced by the spindle 5 and which subjects the workpiece to a slight initial stressing. Upon further rotation of the driving spindle 13, the clutch disc 22 becomes disengagedfrom the sleeve 12 by displacement in the direction A, so that the

hollow spindle

5, 5a, Sbceases to rotate, while the driving spindle 13 is screwed further in thedirection A by being rotated in. the now stationary screw-threaded sleeve 12. As a result the extension 23 of the spindle 13 acts through a power amplifier so as to exert a very substantial displacing force on the push rod ll in the direction of the arrow A, whereby the workpiece 20 is securely plifier consists of three pairs of toggle levers, which are arranged concentrically with respect to the spindle axis, and a

tapered pressure bolt

26 or 26a which is displaceable by the extension 23 of the driving spindle 13 and which has six supporting

surfaces

27 or 27a corresponding to the number of toggle levers, in other words six in the case of the embodiment illustrated.

In the embodiment shown in FIGS. 1 to and 7, each of the toggle levers consists of three steel balls, namely a central steel ball 28 and two end balls 29, and two compression arms 31 which are provided at their ends with bearing cups 30 and which are supported against the

steel'balls

28, 29 by these bearing cups. The end balls 29 are supported on the one hand against an abutment member 32 which is rigidly connected to the spindle extension 5a and on the other hand against an abutment member 33 which is displaceable in the direction of the spindle axis and which acts through the intermediary of a helical compression spring on the push rod 11. Further bearing cups 30 for the end balls 29 are provided in these

abutment members

32, 33. Advantageously all the bearing cups 30 have the form of partspherical segments the radius of curvature of which corresponds with the radius of the balls 29, so that the high compression forces produced are advantageously transmitted via relatively large ball surface areas. In order to ensure that, when the pressure bolt 26 is displaced in the direction of the arrow A, the toggle levers will be forced outwards to a uniform extent, radial guides 35 are provided for the central balls 28 of the toggle levers or the compression members 31 thereof. In the embodiment shown in FIGS. 2, 3, and 7, the

abutment members

32 and 33 have wedge-shaped axial extensions 36, so that the radial guides 35 are formed between them. However, it is advantageous to provide a

guide part

37 or 38, as shown in FIGS. 8, 9 and 10, which is loosely insertable into the spindle extension 5a and has the form of a cylindrical hollow body with

radial grooves

39 or 40 extending throughout its entire length for guiding the central balls 28 or the compression arms 31. This hollow body can, in the case of the embodiment according to FIGS. 8, 9, consist of a diecasting, or else, in the case of the embodiment according to FIGS. 10, ll consist of a sheet metal body comprising wedge-shaped sheet metal segments 41 and sheet metal ,ring 42 which surrounds and securely interconnects these metal segments.

In the case of the embodiment shown in FIGS. 2w 5 and 7, the pressure bolt 26 has a variable taper increasing towards the free end, and longitudinal grooves 27 are formed in this pressure bolt for receiving the central steel balls 28 and supporting them on a circular base line the radius of which corresponds with the radius of the balls. In FIG. 7, the plane of contact of a central ball 28 with the pressure bolt 26 is indicated by a chain dotted line at a, a". In this plane the corresponding supporting surface 27 has a radius of curvature r which corresponds with the ball radius. The central balls 28 thus have no point contact with the pressure bolt, but rather a circular linear contact, so that a more favorable transmission of force between pressure bolt and the six balls 28 is thus achieved. The taper angle of the pressure bolt 26 can be selected to suit working requir'ements or working characteristics, so that a change of the working characteristics of the toggle-lever system can only be obtained by removing the pressure bolt and replacing by one with a different taper angle.

If, as shown, the taper angle of the pressure bolt changes progressively towards the end of the latter, the result can be that, upon the clamping of the vise, i.e. upon rotation of the driving crank 18, a constant driving moment will be obtained, although the transmission ratios in the toggle-lever system constantly change. At the start of the clamping operation, with this varying taper angle a higher rate of feed of the push rod 11 is obtained initially, which then becomes smaller as the clamping force increases. Also a saving in time is achieved, since less revolutions of the driving spindle 13 are necessary for the entire clamping procedure.

In the embodiments illustrated, the pressure bolt 26 acts with six pressure surfaces 27 on six toggle levers or three pairs of toggle levers, so that a favourable power distribution is obtained and with six toggle levers a high clamping force acting on the push rod 11 is achieved. Since each toggle-lever is loaded with only one-sixth of this clamping force, the toggle levers can be of comparatively small dimensions and the wear to which they will be subjected will be correspondingly slight. This wear is further reduced by the use of

steel balls

28, 29, as is customary in the case of ball bearings, and hardened compression arms 31 as well as a hardened pressure bolt 26. Moreover, the space 43 containing the pairs of toggle levers, i.e. the space within the spindle extension 50 between the two

abutment members

32 and 33 is for the most part filled with oil. For sealing this space 43, o-rings 44 are provided between the spindle extension 5a and the

abutment members

33 and 32 or between the pressure bolt 26 and the abutment-32.

Automatic and continuous lubrication of the pair of toggle levers and the pressure bolts is thus obtained. This lubrication is extraordinarily effective in this construction, since, when tightening and loosening the vise, the

spindles

5, 5a, 5b are rotated and, as a. result of this rotation, the oil is always returned to the parts which are subjected to pressure. Wear is thereby very greatly reduced.

As shown in FIG. 6, the central balls 28a of the toggle levers may each be formed with a flat surface 45 by means of which it is supported upon a corresponding one of the inclined surfaces 27a of the pressure bolt 26a. This pressure bolt, by virtue of its flat inclined supporting surfaces 27a, has a uniform taper. It is, however, more advantageous, instead of having sliding frictional contact between the

surfaces

45 and 27a, to provide a rolling contact between them, i.e. while retaining the uniform taper of the pressure bolt, to provide longitudinal grooves 27 instead of the flat surfaces 27a, in which the central balls 28 are supported on a circular base line (as previously described).

In order to be able to alter the working characteristics of the toggle-lever system at will, the several interchangeable pressure bolts may be provided with differing taper angles. Y j

In FIG. 20 there is additionally shown an arrangement in which the pairs of toggle levers 29 to 32 are supported with respect to the hollow spindle 5b via strong plate springs 46. The. result is thereby achieved that the high tension exerted by these plate springs is also maintained when the clamping jaws of the vise somewhat compress'unevennesses in the surface of a workpiece.

OPERATION Referring to FIG. 2, a rotation of the operating spindie 13 by means of the hand crank 18 (or by rotation of the gripping sleeve 16) will cause a rotation of the clutch disc 22 and since same is engaged with the clutch sleeve 12 at 21, the clutch sleeve 12 and therewith the

spindle

5a, 5b which is connected to this clutch sleeve is also rotated and screwed in the bearing block 3 and consequently, according to FIG. 1, moved leftwardly in the direction A (FIG. 2). Since the push rod 11 is supported in said hollow spindle 5 according to FIG. 2, this push rod 11 is also moved to the left and therewith, according to FIG. 1, the slide is also moved. The clamping jaw 9 is thus guided to the workpiece 20 which must be clamped. As soon as a relatively small pretension is achieved, then upon further rotation of the operating spindle 13 the clutch disc 22 disengages with respect to the clutch sleeve 12. The clutch disc 22 is then not further rotated together with the hollow spindle 5, thus is stopped so that during further rotation of the operating spindle 13, the operating spindle 13 is rotated relative to the clutch sleeve-l2. Thus, the operating spindle 13 and its extension 23 are moved in direction A through the threaded connection between the spindle l3 and the clutch sleeve 12 and presses the pressure bolt 26 into the same direction so that this pressure bolt presses the pairs of toggles 31 outwardly. Through this the abutment 33 is moved in direction A and thus also the push rod 11 so that said push rod then according to FIG. I presses the slide 10 farther in direction A. Through this a high press power is achieved and therewith the workpiece 20 is very tightly held.

In a clamping device of this type,-it may happen that during an unclamping of the workpiece, that is during a turning back of the drive spindle, that same is turned back immediately through the friction moment which has been produced by the released clutch 22 so that the torque clutch dog 21 does not again engage in the rec'ess therefor. This has the disadvantage during the next clamping operation that a tensioning power which is too little is applied on the workpiece.

In order to overcome this disadvantage, in the abovementioned clamping device or vise according to the invention, between the push rod 11 and a secondary pressure member (part of the abutment member 33) and axially acting pressure spring 34 is arranged in such a manner that in a not loaded condition between the push rod 11 and the secondary member there exists a distance (b) and during the pretensioning of the workpiece by a screwing of the hollow spindle said spring 34 is compressed. After this compression, the secondary member and the push rod 11 engage one another and at the start of the unclamping procedure during a counterclockwise rotation of the drive spindle through this spindle in the hollow spindle thread, a frictional moment holding said spindle is produced, which is larger than the frictional moment which is applied by the released clutch onto thehollow spindle. Thus, during a releasing of the workpiece, that is during the counterclockwise rotation of the drive spindle l3, first the

hollow spindle

5, 5a, 5b is held until the torque clutch dog 21 engages again and then only during a further rotating back of the drive spindle is the

hollow spindle

5, 5a, 5b turned back.

I claim: l. A mechanical clamping device having means de fining a hollow spindle means rotatably supported on a slide member, said hollow spindle means being threadably engageable in a stationary bearing block and rotatably drivable by means of a hand crank through a drive shaft and a torque coupling, an abutment member axially fixed with respect to said hollow spindle, a longitudinally movable force applying pressing rod and a plurality of toggle lever means expandable in length and being engageable with and positioned between one side of said abutment member and said force applying pressing rod, wherein the improvement comprises means defining a head on one end of said force applying pressing rod housed completely within said hollow spindle means and engaging said toggle lever means, said abutment member including means defining a surface positioned within said hollow spindle means and longitudinally movable pressure bolt means secured to said hand crank means through said torque coupling and being movable longitudinally in response to a driving of said hand crank means and a disengagement of said torque coupling, said pressure bolt means having a tapered surface portion engaging said toggle lever means which effects an expansion of said toggle lever means in response to a longitudinal movement of said pressure bolt means relative to said toggle lever means.

2. The improvement according to claim 1, wherein said hollow spindle means includes a hollow sleeve having wall means at one end thereof, said wall means having an opening therethrough, said force applying pressing rod being slidably disposed in said opening; and

wherein said head is movable between said wall means and said toggle levers.

3. The improvement according to claim 2, wherein each of said toggle lever means comprises a central ball and two end balls and two compression arms which have bearing cups at their ends and which are supported by said bearing cups against said balls, said bearing cups for said balls also being provided on said surface means on said abutment member and on said head.

4. The improvement according to claim 3, wherein said phlfitlity of toggle lever means are concentrically disposed around the axis of said hollow spindle means and are greater than two in number.

5. The improvement according to claim 4, wherein said tapered surface portion on said pressure bolt means engages said central balls.

6. The improvement according to claim 3, wherein each of said bearing cups has the form of a spherical segment, the radius of curvature of whichcorresponds with the radius of the balls.

7. The improvement according to'claim 3, including guide means for at least one of said central balls of said toggle lever means and for said compression arms thereof.

8. The improvement according to claim 7, including a guide part insertable loosely into said hollow spindle means and'has, for the guidance of atleast one of said central balls and said compression members, radial guide grooves which extend over the entire length thereof.

9. The improvement according to claim 8, wherein said guide part consists of wedge-shaped sheet metal segments and a sheet metal ring which surrounds and securely connects said segments.

10. The improvement according to claim 3, wherein said pressure bolt means has means defining several longitudinal grooves therein and in which said central balls are supported on a circular base line, the radius of which corresponds with the radius of the balls.

11. The improvement according to claim 1, wherein said pressure bolt means includes means permitting an interchanging with several pressure bolts having a differing taper angle.

12. The improvement according'to claim 1, wherein larged head and said hollow spindle means.

Claims

1. A mechanical clamping device having means defining a hollow spindle means rotatably supported on a slide member, said hollow spindle means being threadably engageable in a stationary bearing block and rotatably drivable by means of a hand crank through a drive shaft and a torque coupling, an abutment member axially fixed with respect to said hollow spindle, a longitudinally movable force applying pressing rod and a plurality of toggle lever means expandable in length and being engageable with and positioned between one side of said abutment member and said force applying pressing rod, wherein the improvement comprises means defining a head on one end of said force applying pressing rod housed completely within said hollow spindle means and engaging said toggle lever means, said abutment member including means defining a surface positioned within said hollow spindle means and longitudinally movable pressure bolt means secured to said hand crank means through said torque coupling and being movable longitudinally in response to a driving of said hand crank means and a disengagement of said torque coupling, said pressure bolt means having a tapered surface portion engaging said toggle lever means which effects an expansion of said toggle lever means in response to a longitudinal movement of said pressure bolt means relative to said toggle lever means.

2. The improvement according to claim 1, wherein said hollow spindle means includes a hollow sleeve having walL means at one end thereof, said wall means having an opening therethrough, said force applying pressing rod being slidably disposed in said opening; and wherein said head is movable between said wall means and said toggle levers.

4. The improvement according to claim 3, wherein said plurality of toggle lever means concentrically disposed around the axis of said hollow spindle means and are greater than two in number.

7. The improvement according to claim 3, including guide means for at least one of said central balls of said toggle lever means and for said compression arms thereof.

8. The improvement according to claim 7, including a guide part insertable loosely into said hollow spindle means and has, for the guidance of at least one of said central balls and said compression members, radial guide grooves which extend over the entire length thereof.

12. The improvement according to claim 1, wherein said head is enlarged and the space between said abutment member and said enlarged head is for the most part filled with oil and is sealed by O-rings which are arranged between said abutment member, said enlarged head and said hollow spindle means.