Clamping device for hexagon bits

A clamping device has a hexagon receptacle for receiving hexagon bits inserted in an axial direction of the hexagon receptacle. A radially movable locking element is provided for engaging a locking recess of an inserted hexagon bit. The locking element has a rest position and projects in the rest position radially inwardly into the hexagon receptacle. A locking sleeve surrounds the hexagon receptacle in an initial position and has a cylindrical securing wall. The securing wall radially secures the locking element in the rest position. The locking element is axially moveable within the hexagon receptacle into a receiving position in which radial deflection of the locking element is enabled.

BACKGROUND OF INVENTION

1. Field of the Invention

The invention relates to a clamping device having a hexagon receptacle for hexagon bits. The clamping device comprises a radially movable locking element for engagement of a locking recess of the hexagon bit, wherein the locking element projects in a rest position radially inwardly into the hexagon receptacle.

2. Description of the Related Art

Many screw connections are carried out with mechanical or electro-mechanical assist devices, wherein mains-operated or battery pack-operated reversible drills, mechanical ratchet devices or the like are used. As a universally suitable tool, so-called hexagon bits have found great acceptance. These hexagon bits have a substantially hexagonal cross-section and are secured in matching hexagon receptacles, wherein the torque transmission from the hexagon receptacle onto the hexagon bit is realized by surface pressure acting on the lateral surfaces of the hexagon bit. For adaptation to different screwing tasks, an easy exchangeability of the hexagon bits is desirable. Corresponding snap-on connections enable, as needed, the use of bits for screws with slotted head or Philips head, socket bits or other hexagon bits that are adapted to the respective work situation. Hexagon bits having a quarter inch size are a widely accepted international standard.

In operation, securing of the bits in the axial direction was found to be a problem. Hexagon receptacles with integrated magnets are known wherein the magnet is designed to prevent, on the one hand, the inserted bit from accidentally falling out of the receptacle. On the other hand, the bit is to be magnetized in order to ensure adhesion of the screw on the bit. The holding force of the magnet however may not surpass a certain magnitude so that the inserted hexagon bit can be exchanged by hand without tools, for example, when it surpasses a wear limit. In particular, when having carried out a screwing action by applying high torque, it can occur that a hexagon bit remains stuck on the screw head and slips out of the hexagon receptacle when removing the screwing tool. Long bits or specialty bits have a higher weight, and the magnetic holding force can be too small for such bits.

Clamping with a hexagon receptacle are known in which the clamped hexagon bit is secured in the axial direction by means of appropriate locking elements by positive engagement. For this purpose, the hexagon bit has locking recesses, for example, in the form of a circumferential annular groove that is engaged by the locking element. For insertion and removal of such bits, a cumbersome release action is required.

SUMMARY OF INVENTION

It is an object of the present invention to provide a clamping device in which the hexagon bit is reliably secured and which allows easy exchange of the bit.

In accordance with the present invention, this is achieved in that the locking element in the rest position is secured with regard to its radial position by a cylindrical securing wall of a locking sleeve and, in the axial direction of insertion of the hexagon bit, is movable into a receiving position in which a radial deflection of the locking element is enabled.

Accordingly, a clamping device with a locking element is proposed, wherein the locking element in the rest position is secured with regard to its radial position and is movable in the axial insertion direction of the hexagon bit into a receiving position in which a radial deflection is enabled. In this connection, the locking element is in its rest position when no hexagon bit is inserted into the receptacle. For inserting the hexagon bit, the bit is pushed in the axial insertion direction into the receptacle until it strikes the locking element that projects radially inwardly into the hexagon receptacle in the rest position in which it is secured. Upon further pushing of the bit in the insertion direction, the locking element is moved in the axial insertion direction until it reaches its receiving position. In this receiving position, the locking element can be deflected in the radial direction so that the hexagon bit can be inserted completely into its hexagon receptacle. When inserting the bit, an automatic release action for the locking element is provided, and the locking element subsequently can be returned into its rest position for positively securing the hexagon bit in a captive way. The insertion of the bit requires only the insertion step. A separate release action for the locking element is not required.

The locking element is expediently designed such that it is axially movable against the force of a pressure spring that surrounds the hexagon receptacle. After deflection of the locking element into the release position, the locking element can subsequently return automatically into the locked rest position. A manual locking action is not required. A coil spring provided for the above described purpose that surrounds the hexagon receptacle requires only minimal space.

According to an advantageous embodiment, a stop plate is arranged between the locking element and the pressure spring. The stop plate has expediently a radial inwardly slanted portion in the area of the locking element. A precisely defined frictional connection between the pressure spring and the locking element can be obtained. The inwardly oriented slanted portion creates a radial inwardly oriented force component that assists snapping of the locking element into the locking recess of the hexagon bits. According to an advantageous embodiment, the slanted portion is in the shape of a spherical cap; this provides an excellent guiding action of the locking element that is embodied as a ball.

The hexagon receptacle has advantageously a slotted hole in which the locking element is guided in the axial direction. The slotted hole provides with simple means a guiding action of the locking element that is limited in the longitudinal direction of the hexagon receptacle and provides a fixed guide in the circumferential direction.

For a simple and reliable locking or release of the locking element in the radial direction it is advantageous to provide a locking sleeve having a securing wall. The securing wall secures the locking element in its rest position against a radial outwardly oriented movement and locks the locking element in this way. The resulting positive-locking action of the locking element results in a great securing force. The clamped and locked hexagon bit is held captively even under extreme conditions.

For an easy removability of a clamped hexagon bit, the locking sleeve is expediently designed such that it is movable from its initial position in the direction of a free end (receiving end) of the hexagon receptacle against the force of a pressure spring. For removing a clamped and locked bit, the locking sleeve must only be pulled in the same direction as the bit for its removal. When moving the locking sleeve, the locking element is released. The hexagon bit can be removed. The locking sleeve can be simply pulled by two of three fingers of one hand and, at the same time, the bit that is being released in this way can be removed with the same fingers in the same direction. The pressure spring causes an automatic return of the locking sleeve into its initial position so that the locking element is locked in its rest position. Cumbersome separate locking or release steps are not required.

According to an expedient embodiment, on the wall end of the securing wall opposite the free end of the clamping device when viewed in the axial direction, a radial outwardly extending slant is provided. Like the inwardly oriented slanted portion of the stop plate, the slant of the securing wall results in a radial inwardly oriented force component acting on the locking element. The locking element is forced reliably into the locking recess of the hexagon bit. In the axial direction, advantageously on the wall end of the securing wall facing the free end of the clamping device, a radial inwardly extending stop is provided. In this way, a precise relative position of the locking sleeve to the locking element is provided. The axial stroke required upon insertion of the bit for release of the locking element and also the axial release stroke of the locking sleeve for removal of the bit are precisely predetermined and can be adapted to the demands of the operator

For reducing the manufacturing expenditure and for simplifying mounting, the locking sleeve is expediently embodied as a substantially rotational symmetrical rotary part. For an easy release action for removing a clamped bit, the locking sleeve advantageously is provided on its exterior with a surface profiling. The sleeve is easily actuatable even in the case of a soiled environment as well as when using protective gloves.

The locking element is advantageously configured as a ball. The relative movements between the ball, hexagon bit, stop plate, and locking sleeve can be essentially designed such that a rolling action is provided. In this way, only minimal wear will occur.

In the case of a clamping device integrated into the tool shaft of a machine tool, the locking sleeve expediently has an outer diameter that is smaller in comparison to the outer diameter of a drill chuck receptacle on the corresponding end of the tool shaft. When the drill chuck has such a configuration, it can be simply pushed across a mounted clamping device and can be secured on the drill chuck receptacle. Accordingly, retooling e.g. a reversible drill from screwing action to drilling action can be carried out without removal of the clamping device for hexagon bits. The clamping device is captively secured.

DETAILED DESCRIPTION

FIG. 1shows in longitudinal section the tool shaft19of a cordless (power pack-operated) reversible drill in the area of its end20. The tool shaft can also be that of a mains-operated reversible drill or of any other hand-held machine tool. Into the end20of the tool shaft19, a clamping device1for a hexagon bit3is integrated. The clamping device1comprises a hexagon receptacle2that is configured as a unitary (monolithic) part of the tool shaft19. The hexagon receptacle2, in the illustrated embodiment, has a cross-section of a symmetrical hexagon wherein the hexagon bit3that has a matching cross-section is insertable with minimal play into the receiving end of the receptacle in the axial insertion direction indicated by arrow6. Instead of the hexagon cross-section of the hexagon receptacle2, it is also possible to employ a suitable triangular cross-section or the like. It may also be expedient to employ instead of a receptacle for the clamping device1that is integrated into the tool shaft19a separate component as a clamping device1, for example, for attachment in a three-jaw chuck, in a ratchet device or the like.

A locking element4is provided that is embodied as a ball18in the illustrated embodiment. It is also possible to employ a pawl-shaped locking element4, a spring wire or the like. The looking element4is secured in a slotted hole11provided in the hexagon receptacle2and projects radial inwardly into the hexagon receptacle2. The hexagon receptacle2is provided on its exterior with a locking sleeve13that extends approximately across the entire length of the receptacle2. The locking sleeve13is configured as a rotary part having rotation symmetry. On its inner side, the locking sleeve13has a circumferentially extending cylindrical securing wall12that rests on the exterior of the locking element4. The locking element4is illustrated in its rest position and secured by the securing wall12against movement in a radial outward direction.

By means of a pressure spring7that is embodied as a coil spring8, a stop plate9is forced axially against the locking element4in the direction of the free end14of the clamping device1. The stop plate9rests by means of a radial inwardly oriented slanted portion10against the locking element4so that the locking element4is pretensioned radially inwardly and axially in the direction of the free end14. The slanted portion10can be embodied as a plane, as a spherical cup or the like. Because of the axial force component, the locking element4rests against an end of the slotted hole11facing the free end14and also against a stop17of the locking sleeve13. The stop17extends radially inwardly on the wall end of the securing wall that faces the free end14. In the rest position of the locking element4illustrated inFIG. 1, the hexagon bit3is insertable in the direction of arrow6until it strikes the locking element4that projects inwardly into the hexagon receptacle2.

The locking element4is movable within the slotted hole11against the tensioning force of the pressure spring7in the direction of the arrow6in the axial direction of the receptacle2.

In the area of the end20the tool shaft19has a drill chuck receptacle21on which, for example, a three-jaw chuck can be secured. The outer diameter D2of the chuck receptacle21is greater than the outer diameter D1of the locking sleeve13.

FIG. 2shows the arrangement ofFIG. 1with the hexagon bit3having been inserted farther in comparison to the position ofFIG. 1. The locking element4has been moved by the hexagon bit3axially in the direction of arrow6relative to the rest position illustrated inFIG. 1and is now in the receiving (release) position. In the illustrated receiving position, the locking element4has been axially moved relative to the securing wall12such that the securing wall12is no longer positioned at the radially outwardly oriented side of the locking element4. The locking element4has been moved radially outwardly in the illustrated receiving position that it no longer projects into the hexagon receptacle2and releases the passage (bore) of the receptacle2. From the position illustrated inFIG. 2, the hexagon bit3can now be moved completely up to the stop26, and the locking element4is forced by the force of the pressure spring7in the axial direction against the slant16.

In the illustrated embodiment, one locking element4is provided; accordingly, the illustrated axial deflection has caused the stop plate9to be in a slanted position. The slanted portion10of the stop plate9is angled inwardly to such an extent that even for the slanted position of the stop plate9, the slanted portion10exerts a radially inwardly acting force component onto the locking element4and prevents a complete movement of the locking element4in the outward direction. It is also possible to employ two or more locking elements4.

FIG. 3shows the arrangement according toFIGS. 1 and 2where the hexagon bit3has been inserted to the point of striking the stop26. The hexagon bit3has a locking recess5that, in the illustrated embodiment, is configured as a circumferential groove. It is possible to provide recesses having different configurations, for example, blind bores or the like. The slanted portion10of the stop plate9and the slant16of the locking sleeve13(FIG. 2) effect via the pressure force of the pressure spring8a radial inwardly oriented force component as a result of which the locking element4is forced into the locking recess5. When the locking element4illustrated inFIG. 2rolls or glides along the outer contour of the hexagon bit3into the locking recess, it is first radially inwardly moved by means of the stop plate9into the locking recess5and is subsequently moved in the axial direction into the rest position illustrated inFIG. 3. The securing wall12of the locking sleeve13positively surrounds the exterior of the locking element4. The rest position illustrated inFIG. 3of the locking element4corresponds to the rest position according toFIG. 1. By engaging the locking recess5, the radially outwardly secured locking element4effects according toFIG. 3a positive-locking and captive securing action of the hexagon bit3in the axial direction.

The locking sleeve3is slidingly guided in the axial direction on the exterior of the hexagon receptacle2. In the area of the free end14, at the inner side of the locking sleeve13a pressure spring15is arranged; it is supported with one end on the flange surface27of the locking sleeve13and with the opposed end on the stop ring23. The stop ring23is supported in the axial direction by means of a spring ring24arranged in a circumferential groove25. The locking sleeve13is slidingly movable against the force of the pressure spring15in the direction of the free end14and thus in the direction opposite to the arrow6that indicates the insertion direction.

For removal of the hexagon bit3from the clamping device1, the locking sleeve13can be moved in accordance withFIG. 4against the force of the pressure spring15in a direction counter to the insertion direction6. Under the effect of the pressure force of the coil spring8, the locking element4still rests against the end of the slotted hole11that is located at the side of the free end14. The locking sleeve13is moved to such an extent counter to the insertion direction6that the securing wall12no longer surrounds the exterior side of the locking element. The locking element4is radially outwardly released and has moved so far outwardly that it no longer projects into the hexagon receptacle2or the locking recess5. The hexagon bit3can be removed in a direction opposite to the insertion direction6. The removal direction of the bit and the pulling direction of the locking sleeve13required for bit release coincide accordingly. Pulling the locking sleeve13from the position illustrated inFIG. 3into the position ofFIG. 4and the removal in the same direction of the hexagon bit3can be carried out simultaneously and with one hand. For improving gripping of the locking sleeve13, the sleeve13is provided on the exterior with a surface profiling that is formed by two circumferentially extending grooves22in the illustrated embodiment.

After release of the locking sleeve13, it is automatically moved into the position illustrated inFIG. 1under the action of the pressure spring15, wherein, by means of the slant16and of the slanted portion10of the stop plate9, the locking element4is forced radially inwardly into the position where it projects into the hexagon receptacle2and thus into the rest position ofFIG. 1.