EP1844905A2 - Tool collet - Google Patents

Abstract

The chuck has a wear-resistant guide unit located in a rotatable sleeve-shaped base body (1). The guide unit is connected with the base body for joint rotation and includes a projecting radially inwardly rotation-imparting unit. The guide unit is formed of two guide shells (6, 7) of a wear-resistant material, where the shells are radially displaceable in the base body in certain limits and form a projecting radially inwardly spherical cap (9). The shells are supported in the base body for a limited axial displacement. The base body forms a working tool side axial stop band.

Description

The invention refers to a tool holder for an at least partially rotating and / or punching tool, such as a drill bit, chisel or cutting bit for machining stone, concrete or masonry.

Usually, a tool holder for a spigot end of a tool of a hand tool rotating and hammering driven tool, for example, accordingly DE2618596 an insertion sleeve extending along an axis and having inner cylinder jacket-shaped guide surfaces and radially inwardly projecting rotary driving webs and radially inwardly displaceable locking bodies, which engage in locking grooves of the associated insertion end of the tool and limit the axial mobility of the tool. The torque is transmitted on the machine side with the two rotary driving webs, which dip into two corresponding trapezoidal grooves of the tool. The shape of the locking grooves corresponds approximately to the shape of the locking body, usually balls. Due to the necessary for the transmission of a given torque to the tool high surface pressure with respect to the guide surfaces radially inwardly disposed rotary support webs are subjected to high wear, which limits the life of the tool holder. Especially when tool holders for hand tools used in construction, which process brittle materials such as concrete and masonry and produce abrasive overburden, a low wear of the tool holders for the reliability of the power tool is important. Rotary hammers are becoming ever more powerful with each new generation and the operating times of the hand-held power tools are increasing, along with more comfortable working habits, through more intensive use. Better tools make it possible to use drill bits with larger bore diameters. These conditions limit and reduce the service life of the previously used tool holders. The failures are particularly evident due to abrasive wear of various contact partners such as: Torque driving webs opposite the trapezoidal grooves; Ball in grooves of the insertion end; Ball and their recordings and support surfaces in the tool holder.

After US3525531 and the DE10044387 is a tool holder with a separate, wear-resistant guide sleeve with radially inwardly projecting rotary driving means previously known.

In addition, after the DE3416964 the tool holder on a separate, wear-resistant guide sleeve, which forms a locking element on one side. To accommodate the insertion with closed at the end locking grooves, the guide sleeve on the locking element opposite side is half-way open, whereby the insertion can be tilted obliquely into the tool holder. However, this has the disadvantage that the insertion end is unguided in this axial position, which is not suitable for powerful hand tool machines.

In addition to the wear problem, the tool holder is heavily loaded when the tool strikes the Verrieglungselementen the tool holder in the case of idle and before the large kinetic energy of the tool friction can not be reduced over a very short free travel. The tool moves after a hard push again against the striker and thus in turn activates the percussion, making this process repeats periodically.

The object of the invention is the realization of a heavy-duty tool holder long service life.

The object is essentially achieved by the features of claim 1. Advantageous developments emerge from the subclaims.

Thus, a tool holder for an at least partially rotating and / or impacting tool has a rotatably drivable sleeve-shaped base body which rotatably receives a wear-resistant guide means inside which has radially inwardly projecting rotational drive means, wherein the guide means consists of at least two guide shells made of wear-resistant material, of which at least one limited in the body radially displaceable and forms a radially projecting locking body in itself.

Due to the two wear-resistant guide shells with rotary driving means a heavy-duty guide means is present, wherein the wear-resistant contact pairing: locking body - guide sleeve is eliminated by the trained in itself radially einkragenden locking body in one of the limited radially displaceable guide shells. The locking / unlocking takes place after radial pivoting out of Guide shells by tilting the tool out of the coaxial orientation in which it is circumferentially guided in the locked position.

Advantageously, the locking body is a spherical cap, whereby a compatibility with conventional tool holders is given with a locking ball.

Advantageously, at least the guide shell formed with the locking body in the base body axially movable, whereby it is displaced in the direction of impact in the strike direction and prevents too far backward movement of the tool, whereby periodically repeated clearances are avoided.

Advantageously, the rotary driving means are at least two radially inwardly projecting, longitudinally extending rotational support webs, whereby a compatibility with conventional tool holders is given with two or three rotary driving webs.

Advantageously, the rotary driving means are all formed on the guide shell without radially projecting locking body, whereby only this is tilted with the tool.

Advantageously forms at least the guide shell with rotational driving means radially outwardly projecting shell rotating means, further advantageously longitudinally extending webs, which in turn engage in suitable Drehitnahmeausnehmungen of the body, whereby the transmission of torque from the body to the rotationally-transmitting guide shell takes place.

Advantageously, the base body forms a bevel to an inner radial extension, whereby at least the guide shell having the locking body in the radial extension is radially displaceable.

Advantageously, the guide shells located in the locking position form a substantially circumferentially closed receiving area for the insertion end of the suitably associated tool, whereby the penetration of abrasion into further spatial areas of the tool holder is limited.

Advantageously, the guide shells are axially positively connected with each other, further advantageous over a coarse axial toothing, whereby their axial movements are coupled.

Advantageously, the guide shells are tool-side via a form-fitting, which further advantageously projecting radially outward collar-shaped, connected to an elastic dust cover, whereby an elastic pivot point for the guide shells is formed over this.

Advantageously, the base body forms a tool-side axial stop collar, as a result of which it is possible for the guide shells to abut radially outwardly projecting stop surfaces.

Fig. 1

als Werkzeugaufnahme im Querschnitt nach Ebene I-I in Fig. 2 in Verrieglungsposition

Fig. 2

als Werkzeugaufnahme im Längsschnitt nach Ebene II-II in Fig. 1 in Verrieglungsposition (obere Bildhälfte in Leerschlagposition, untere Bildhälfte in Schlagposition)

Fig. 3

als Werkzeugaufnahme im Längsschnitt in Entriegelungsposition

The invention will be explained in more detail with respect to an advantageous embodiment with:

Fig. 1

as a tool holder in cross section to level II in Fig. 2 in Verrieglungsposition

Fig. 2

as a tool holder in longitudinal section on the plane II-II in Fig. 1 in Verrieglungsposition (upper half of the picture in empty spot position, lower half of the picture in striking position)

Fig. 3

as a tool holder in longitudinal section in unlocking position

Referring to FIGS. 1 and 2, a tool holder has a sleeve-shaped base body 1, which is the machine side releasably connected to a rotary-driving tubular machine spindle 2, which performs an axially reciprocating striker 3, the impact energy of the hammer drill hammer not shown on the insertion 4 transmits a tool not shown. At the tool-side end of the base body 1 are two axially positively connected via an axial toothing 5, guide shells 6 and 7 made of highly wear-resistant steel radially supported and mounted axially movable, which center the insertion 4 coaxially and lead (locking position). The torque transmission takes place via the guide shell 7, the two diametrically arranged, longitudinally extending Drehmitnahmestege 10 engage in the machine side open rotary drive grooves 11 of the insertion end 4. The shell turning means 12 in the form of diametrically arranged outer webs of the guide shell 7 engage in matching longitudinal grooves 13 of the base body 1 a. The guide shells 6 and 7 located in the locking position form a circumferentially closed receiving region for the insertion end 4 of the suitably associated tool.

In the operating case of hammer drilling shown in the lower half of Fig. 2, the tool is pressed with the insertion end 4 against the substrate, not shown. As a result, the guide shell 6 is displaced into an axial center position of the main body 1 via the locking groove 8 and the locking body 9, the guide shell 7, which is axially positively connected to the guide shell 6 via an axial toothing 5, moving into the same axial central position. The movement is limited by an axial stop of the insertion end 4 on the striker 3 (impact position). The axial movements of the insertion end 4 required in the hammer drilling operation are ensured by a usual sufficient difference in length between the locking groove 8 and the locking body 9.

In the blank image shown in the upper half of FIG. 2, the machine tool lifts off the ground, triggered by the impulse of the striker 3 moves the tool with the insertion 4 something tool side axially out of the tool holder and strikes with the axial boundary 14 of the locking groove 8 the locking body 9, which the guide shell 6 and the axial toothing 5 and the guide shank 7 slightly tool axially moved out of the tool holder until the guide shells 6 and 7 with their defined stop surfaces 15 on a Axialanschlagbund 16 of the body 1 strike a large area (idle position). Due to the friction between the insertion 4 with the guide shells 6 and 7, the two guide shells 6 and 7 against each other, the two guide shells 6 and 7 relative to the base body 1, the kinetic energy of the tool is degraded, whereby the insertion end 4 comes to rest in an axial position , in which no impact contact with the striker 3 is more possible.

When inserting the tool, the user pushes the insertion end 4 through the sealing lips 17 of the elastomeric dust cover 18 along the guide surfaces 19 of the guide shells 6 and 7 a. The case at the tool-side leading edge 20 of the locking body 9 abutting insertion 4 moves the guide shells 6 and 7 relative to the main body 1 machine side axially in an unlocking position shown in Fig. 3, in which by the compulsion of the inserted insertion 4, the machine-side ends of the guide shells. 6 and 7 open radially outward. The coaxial about a Verkippwinkel [alpha] tilted shank 4 can now dive under the locking body 9. The spring force of a compression spring 21 then moves the elastic dust cap 18 and by means of a collar-shaped radially outwardly projecting positive connection 22 with this articulated guide shells 6 and 7 back to its locking position (shown in Fig. 2 in the upper half), which via a Bevel 23 of the body 1 with her Machine-side end to be moved radially inwardly, wherein the locking body 9 is immersed in the locking groove 8. The elastic positive fit 22 serves as a fulcrum for the guide shells 6 and 7. The dust cap 18 forms with the integrated sealing lip 17 a dust seal and with other sealing parts 24 of the tool holder a labyrinth against unwanted dust entry to the base body 1.

To remove the tool from the tool holder, the user offset against the spring force of the compression spring 21, the dust cap 18 on the machine side axially. About the positive connection 22, the guide shells 6 and 7 are also axially offset from its locking position (shown in Fig. 2 in the upper half of the picture) and radially unlocked from the base body 1. When pulling out of the insertion end 4, the guide shells 6 and 7 on the compulsion of the insertion end 4, formed by the axial limitation 14 of the locking groove 8, offset radially outward about the pivot point of the positive connection 22. The now coaxial about the tilt angle [alpha] tilted shank 4 is axially free and can be removed. The spring force of the compression spring 21 then sets the guide shells 6 and 7 and the dust cap 19 back to the idling position (shown in Fig. 2 in the upper half).

Claims (11)

Tool holder for an at least partially rotating and / or impacting tool having a rotatably drivable sleeve-shaped base body (1) radially rotatably inside a wear-resistant guide means receives, which radially inwardly einkragende rotary driving means, characterized in that the guide means of at least two guide shells (6 , 7) consists of wear-resistant material, of which at least one in the base body (1) is limited radially displaceable and a radially projecting locking body (9) in itself forms. Tool holder according to claim 1, characterized in that the locking body (9) is a spherical cap. Tool holder according to claim 1 or 2, characterized in that at least the guide shell (6) with the locking body (9) in the base body (1) is formed axially limited movement. Tool holder according to one of claims 1 to 3, characterized in that the rotary driving means are at least two radially inwardly projecting, longitudinally extending rotary driving webs (10). Tool holder according to one of claims 1 to 4, characterized in that all rotary driving means on the guide shell (7) without radially einkragenden locking body (9) are formed. Tool holder according to one of claims 1 to 5, characterized in that at least the guide shell (7) with rotational driving means radially outwardly projecting shell rotating means (12) is formed. Tool holder according to one of claims 1 to 6, characterized in that the base body (1) forms a bevel (23) to an inner radial extension. Tool holder according to one of claims 1 to 7, characterized in that located in the Verrieglungsposition guide shells (6, 7) form a substantially circumferentially closed receiving area for the insertion end (4) of the matingly associated tool. Tool holder according to one of claims 1 to 8, characterized in that the guide shells (6, 7) are axially positively connected with each other. Tool holder according to one of claims 1 to 9, characterized in that the guide shells (6, 7) on the tool side via a positive connection (22) with an elastic dust cap (18) are connected. Tool holder according to one of claims 1 to 9, characterized in that the base body (1) forms a tool-side Axialanschlagbund (16).

Images