EP2543814B1 - Chisel holder and chisel holder system with a chisel holder and a base section - Google Patents

Description

The present invention relates to a bit holder comprising a body portion having a bit receiving opening open at least to a bit insertion side of the body portion and a shaft extending from a support side of the body portion having a shaft longitudinal axis, the body portion having a first support surface portion on its support side according to the preamble of claim 1.

A bit holder for a road milling machine or the like is known from DE 43 22 401 C2 known. The chisel receiving opening of this known chisel holder is open at its end remote from the chisel insertion side, ie at the support side, to the first support surface area. In an area laterally adjacent to the chisel receiving opening portion of the body portion, the attachment shaft extends from the body portion. In a provided for such a bit holder base part which is to be fixed to a milling drum or the like by welding, a first counter-Abstützflächenbereich is provided in association with the first Abstützflächenbereich. When introduced into a mounting shank receiving opening of the base member mounting shank of the first support surface area of the chisel holder on the first counter-Abstützflächenbereich of the base part, so that in principle a defined positioning of the chisel holder is predetermined on the base part. A clearance is provided between the attachment shaft-carrying portion of the body portion and the opposite side of the base member to provide a so-called bit holder retention space which allows deeper penetration of the attachment shaft into the attachment shaft receiving aperture when in the region of the first support surface portion and / or the first counter-Abstützflächenbereichs wear occurs.
Although the first support surface region and thus also the first counter-support surface region are approximately orthogonal to a chisel receiving opening longitudinal axis and thus also a longitudinal chisel axis, transverse stresses may arise in the milling operation, which leads to considerable torsional and shear stress where the attachment shaft adjoins the body region. which may also lead to a demolition of the mounting shaft in unfavorable cases in the design of the mounting shaft with a comparatively large shaft cross-sectional area.

At one of the WO 2010/01593 A1 known chisel holder according to the preamble of claim 1, a body receiving a chisel is formed so that two support surface areas are formed on the support side. To one of these Abstützflächenbereiche the bit receiving the bit receiving opening is open and in the other Abstützflächenbereich essentially the Befestigungsschafft is formed extending away from the body region.
The DE 10 2005 017 760 A1 discloses a bit holder in which a fastening shaft extending from the body portion is tapered and insertable into a complementarily shaped opening of a base member. On both sides of the mounting shank supporting surface areas are provided on the body region, which are brought to bear against the same trained counter-Abstützflächenbereichen of the base part to the plant.
At one of the US 2008/0093912 A1 Known chisel holder is a chisel receiving chisel receiving opening in the region of a first Abstützflächenbereichs open on a support side. The first support surface area comprises two mutually angled support surfaces. Adjacent to each of these support surfaces extends a mounting shaft.

From the DE 20 2007 013 350 U1 a chisel holder is known. A bit receiving hole provided for receiving a bit extends toward a substantially planar first pad area on a support side of the body portion of the bit holder. Adjacent to the first support surface area, a fixing shaft extends on the support side of the body region. On both sides of the mounting shank surfaces are provided angled to the first Abstützflächenbereich over which comminuted by the chisel soil is discharged to both sides of the mounting shaft.
It is the object of the present invention to provide a chisel holder and a chisel holder system with a chisel holder and a base part, in which a lower mechanical load, in particular of the mounting shank can be achieved with optimized force application.
According to a first aspect, this object is achieved by a bit holder according to claim 1. This comprises a body portion having a chisel receiving opening open at least to a bit insertion side of the body portion and a fixing shaft having a shaft longitudinal axis extending from a support side of the body portion, the body portion having a shaft side at its support side having first support surface area.
In this case, it is further provided that the body region has on its support side a second support surface region angled relative to the first support surface region and that the first support surface region comprises a first support surface and a second support surface angled relative to the first support surface.

In the case of the chisel holder constructed according to the invention, a relief of the attachment shaft in its adjoining the body region is made possible by the larger surface area and by means of the angling self-centering support Section reached. Furthermore, in the bit holder according to the invention by the Anwinkelung two support surfaces of the first Abstützflächenbereichs equally centering of the bit holder and thus reducing the introduced in the mounting shank transverse forces is achieved. This also contributes to a lower load on the mounting shaft.

In order to enable easy access to a bit received in the bit receiving opening in the bit holder according to the invention and optimizing the centering feature provided thereon, the bit receiving opening is substantially open to the support side in the area of the first support surface area. The attachment shaft extends substantially in the region of the second support surface area from the body region.

The centering property of the chisel holder constructed according to the invention is further improved by the fact that the second support surface region comprises a first support surface and a second support surface angled relative to the first support surface. Since the first Abstützflächenbereich has two mutually angled support surfaces, a total of four mutually pyramidal angled, in particular a funnel-like configuration resulting supporting surfaces are provided on the bit holder, which avoids or at least reduces a force introduction into the mounting shank and thus a significant reduction in the burden of the same, especially transverse to brings his shaft longitudinal axis with it.

In this case, a load which is very uniform with regard to the introduction of force can be achieved if the first support surface and the second support surface of the first support surface region and / or of the second support surface region are arranged substantially symmetrically with respect to a holder center plane. It should be noted here that the holder center plane essentially represent the geometric center of the chisel holder can and can be clamped, for example, by the shaft longitudinal axis and a longitudinal axis of the chisel receiving opening.

In order to optimize the loads occurring in the milling operation, it may further be provided that a first angle enclosed between the first support surface and / or the second support surface of the first support surface region and the second support surface region is in the range of 127 ° to 147 °, preferably approximately 137 ° and / or a second angle included between the first support surface and the second support surface of the first support surface region in the range of 120 ° to 140 °, preferably about 130 °, and / or enclosed between the first support surface and the second support surface of the second support surface region third angle in the range of 100 ° to 120 °, preferably at about 110 °, and / or between a transition region between the first support surface and the second support surface of the first support surface region and a transition region between the first support surface and de The second support surface of the second support surface area enclosed angle is in the range of 121 ° to 141 °, preferably at about 131 °.

Since, for manufacturing reasons, the various support surfaces of the chisel holder constructed according to the invention are essentially flat, ie not curved, it is proposed to allow a direct transition of such support surfaces into each other that at least one support surface of the first support surface region and the second support surface region in a line-like and / or straight Connect extending first transition area together.

According to another particularly advantageous aspect for manufacturing reasons, it is proposed that the first support surface and the second support surface of the second support surface region adjoin one another in a planar or / and straight extending second transition region. It has been shown that in particular during production the chisel holder as a forging in the transition region between the two support surfaces of the first Abstützflächenbereichs an approximately flat, area-like area arises, which can be processed in a simple manufacturing technology to a planar or straight extending second transition area. In particular, it may be provided that the second transition region comprises a transition surface substantially orthogonal to the holder center plane.

In order to minimize the forces acting on the attachment shaft transversely to the longitudinal axis of the shaft and to load it in shear in the adjoining region on the body region, it is proposed that a longitudinal center axis of the bit receiving opening and the shaft longitudinal axis be at an angle of 10 ° to 15 °, preferably approximately 12 , 5 °, are inclined to each other. This angle has therefore proven to be particularly advantageous, since it has been shown that in milling operation, the forces acting on a chisel are generally not parallel to its longitudinal axis and therefore not in the direction of the longitudinal axis of the chisel receiving opening, but slightly inclined. This inclination can be accommodated by the employment of the shaft longitudinal axis with respect to the longitudinal axis of the chisel receiving opening.

According to a further advantageous aspect, the attachment member application area may comprise a attachment member engagement surface, and the shaft longitudinal axis and a surface normal of the attachment member engagement surface may be inclined to each other at an angle of 50 ° to 65 °, preferably about 62.5 °. By this comparatively small employment of the surface normal of the Befestigungsorganbeaufschlagungsfläche to the shaft longitudinal axis is achieved that an approximately in the direction of this surface normal to the Befestigungsorganbeaufschlagungsfläche by means of a fastening member force applied as little as possible inclined to the shaft longitudinal axis, so this as strong as possible loaded in the direction of its longitudinal axis. This also cross-loads can be reduced in the shaft, however, such a Orientation of a trained example as a bolt fastener to be ensured that when used in a base part tool holder access to the attachment member.

According to a further aspect, there is provided a bit holder system comprising a bit holder constructed according to the invention and a base part having a first counter-support surface region for supporting the first support surface region.

This bit holder system is characterized by a second counter-support surface area angled relative to the first counter-support surface area for supporting the second support surface area, and / or in that the first counter-support surface area includes a first counter-support surface for supporting the first support surface of the first support surface area and a respect the second counter-support surface angled against the first counter-support surface for supporting the second support surface of the first support surface region.

With this configuration of the base part on its counter-support side, a configuration complementary to the design of the chisel holder is obtained, so that an optimal mating of these two components is ensured.

In particular, provision can be made for the angling of the first support surface area with respect to the second support surface area and the angling of the first counter support surface area with respect to the second counter support area and / or the angling of the first support surface with respect to the second support surface of the first support surface area and the angling of the first Counter-support surface with respect to the second counter-support surface of the first counter-Abstützflächenbereichs are complementary to each other.

As with the chisel holder itself, a further improved centering effect can also be achieved in the chisel holder system in that the second counter-support surface region has a first counter-support surface for supporting the first support surface of the second support surface region and a second counter-support surface angled relative to the first counter-support surface for supporting the second support surface of the second support surface area. In this embodiment too, in order to obtain an optimum fit of the bit holder in the base part, provision can be made for the angling of the first support surface with respect to the second support surface of the second support surface region and the angling of the first counter-support surface relative to the second counter-support surface of the second counter support surface region are complementary to each other.

According to a particularly advantageous aspect of the present invention, it is proposed that the first counter-support surface and the second counter-support surface of at least one counter-support surface area adjoin one another in a countersink-like third transition region. Since, as with the various support surfaces, advantageously also the various counter-support surfaces are each provided with a substantially planar, ie not curved configuration, the provision of a sinking transitional region between such counter-support surfaces, the occurrence of notch stresses under heavy load is avoided. Similarly, in such a recess-like third transition region, a volume is kept free, into which, for example, a straight extending transition region between two support surfaces of a Abstützflächenbereichs or two Abstützflächenbereiche can dive without abutting in this area chisel holder and base member to each other. Thus, further volume is kept ready to allow for the occurrence of wear at least a slight resetting of the bit holder.

To further support this, it may be provided that the first counter-support surface region and the second counter-support surface region in connect a recess-like fourth transition area together.

In order to provide a loading direction which deviates as little as possible from the shaft longitudinal axis with a fastening force for fixing the fastening shaft in the base part, it is further proposed that a fastening shaft receiving opening with a fastening shaft receiving opening longitudinal axis and a fastening element receiving opening with an attachment member receiving opening longitudinal axis are provided in the base part and that the fastening shaft receiving opening longitudinal axis and the attachment member receiving opening longitudinal axis at an angle of 50 ° to 65 °, preferably about 62.5 °, are inclined to each other.

Fig. 1

eine perspektivische Ansicht eines Meißelhalters in Blickrichtung I in Fig. 2;

Fig. 2

eine perspektivische Ansicht des Meißelhalters der Fig. 1 in Blickrichtung II in Fig. 1;

Fig. 3

eine Ansicht des Meißelhalters in Blickrichtung III in Fig. 2;

Fig. 4

eine Schnittansicht des Meißelhalters, geschnitten in einer Haltermittenebene;

Fig. 5

eine Ansicht des Meißelhalters in Blickrichtung V in Fig. 1;

Fig. 6

eine Seitenansicht des Meißelhalters;

Fig. 7

eine Schnittansicht des Meißelhalters im Bereich eines Befestigungsschafts, geschnitten längs einer Linie VII-VII in Fig. 6;

Fig. 8

eine Schnittansicht des Meißelhalters im Bereich eines Befestigungsschafts, geschnitten längs einer Linie VIII-VIII in Fig. 6;

Fig. 9

eine perspektivische Ansicht eines Basisteils;

Fig. 10

eine Ansicht des Basisteils der Fig. 9 in Blickrichtung X in Fig. 9;

Fig. 11

eine perspektivische Darstellung des Meißelhalters und des Basisteils im Zusammenbau;

Fig. 12

eine Schnittdarstellung des Zusammenbaus der Fig. 11, geschnitten in der Haltermittenebene.

The present invention will be described below in detail with reference to the accompanying drawings. It shows:

Fig. 1

a perspective view of a chisel holder in the direction I in Fig. 2 ;

Fig. 2

a perspective view of the chisel holder of Fig. 1 in viewing direction II in Fig. 1 ;

Fig. 3

a view of the chisel holder in the direction of III in Fig. 2 ;

Fig. 4

a sectional view of the chisel holder, cut in a Haltermittenebene;

Fig. 5

a view of the chisel holder in the direction V in Fig. 1 ;

Fig. 6

a side view of the chisel holder;

Fig. 7

a sectional view of the bit holder in the region of a mounting shaft, taken along a line VII-VII in Fig. 6 ;

Fig. 8

a sectional view of the chisel holder in the region of a fastening shaft, taken along a line VIII-VIII in Fig. 6 ;

Fig. 9

a perspective view of a base part;

Fig. 10

a view of the base part of Fig. 9 in the direction X in Fig. 9 ;

Fig. 11

a perspective view of the chisel holder and the base part in the assembly;

Fig. 12

a sectional view of the assembly of Fig. 11 , cut in the holder center plane.

The Fig. 1 to 6 show a bit holder, generally designated 10, for a milling drum of a road milling machine. The bit holder 10 includes a body portion 12 having an approximately cylindrical projection 16 extending therefrom at a bit insertion end generally indicated at 14. In the cylindrical projection 16, a bit receiving aperture 18 is provided therethrough or the entire body portion 12. This is open at the bit insertion side 14 for receiving an interchangeable chisel lockable therein by friction pinch seat and is open at a support side 20 of the body portion 12 substantially opposite to the bit insertion side 14. From this side, a tool used to remove a worn bit from the bit receiving aperture 18 may be inserted to force the bit out of the bit hole 18.

On the body region 12, on the support side 20, a first support surface region 22 and an angled second support surface region 24 intended. It can be seen in the illustrations that the chisel receiving opening 18 in the region of the first support surface area 22 is open towards the support side 20. Essentially starting from the second support surface region 24, an elongated attachment shaft 26 extends from the body region 12. The attachment shaft 26 is formed with a generally circular, eg circular or oval or elliptical, outer peripheral contour. On the structural design of the mounting shank 26 will be discussed in more detail below.

The first support surface region 22 comprises a first support surface 28 and a second support surface 30. These two support surfaces 28, 30 of the first support surface region 22 are angled toward one another and to a holder center plane, which is substantially the plane of the drawing Fig. 4 corresponds, formed substantially symmetrical or employed at the same angle. It should be noted here that the holder center plane can be clamped, for example, by a longitudinal axis L _{M of} the chisel receiving opening 18 and a shank longitudinal axis L _{B of} the mounting shank 26.

The second support surface region 24 comprises a first support surface 32 and a second support surface 34. The two support surfaces 32, 34 are angled to each other and thus angled to the holder center plane, in which case the embodiment with respect to the Haltermittenebene corresponding to the configuration of the two support surfaces 28, 30 of the first Support surface area 22 may be symmetrical.

Between the first support surface 28 of the first support surface region 22 and the first support surface 32 of the second support surface region 24 and equally between the second support surface 30 of the first support surface region 22 and the second support surface 34 of the second support surface region 24 are line-like and preferably straight extending first transition regions 36, 38th formed, which equally also a transition between the first support surface area 22 and the define second support surface area 24. One recognizes in particular in the Fig. 1 and 2 clearly that these first transition regions 36, 38 is formed on an edge-like adjoining region of the respective support surfaces. Due to the fact that the support surfaces 28, 30, 32, 34 are preferably all flat, that is, not curved, these are thus also line-like first transition regions 36, 38 according to uncrimped.

A second transition region 40 formed between the first support surface 32 and the second support surface 34 of the second support surface region 24 is formed with a substantially straight transition surface 42. This is essentially orthogonal to the holder center plane. Since the two support surfaces 32, 34 are substantially planar, that is to say unconstrained, this second transition region 40 also extends substantially rectilinearly.

Where the two support surface areas 22, 24 or their support surfaces 28, 30 and 32, 34 adjacent to each other, ie at the first transition regions 36, 38, an angle W _{1 is} formed, which is in the range of about 137 °. An angle W ₂ of approximately 130 ° is formed between the two support surfaces 28, 30 of the first support surface region 22, so that each of these support surfaces 28, 30 has an inclination angle of approximately 65 ° to the holder center plane. Between the two support surfaces 32, 34 of the second support surface area 24, an angle W ₃ of about 110 ° is formed, so that each of these support surfaces 32, 34 has an inclination angle of about 55 ° to the holder center plane. This generally means that the two support surfaces 28, 30 of the first support surface region 22 are disposed at a larger angle therebetween than the two support surfaces 32, 34 of the second support surface region 24. Further, the shaft longitudinal axis L _B is oriented with respect to the body region 12 such that the attachment shaft 26 is inclined to the first support surface region 22 and the second support surface region 24 at an angle W ₄ and W ₅ , which is at about 65 °. For example, the angle W _{4 are} in the range of 67 °, while the angle W ₅ may be about 64 °. It should be pointed out here that in order to determine these angles W ₄ or W _5, a line connecting the respective support surfaces 28, 30 or 32, 34 in the case of imaginary extension thereof can be used or, in the case of the support surfaces 32, 34, the angle W. ₅ also with respect to the transition surface 42 of the second transition region 40 and in the case of the support surfaces 28, 30 of the angle W ₄ with respect to a transition surface 43 of another transition region 41 on the bit holder 10 can be determined. The total angle formed by the sum of the two angles W ₄ and W ₅ can thus be in a range of approximately 131 ° and defines the angle of attack of two prism-like configurations, one of which is defined by the two support surfaces 28, 30 of the first support region 22 and Other is defined by the two support surfaces 32, 34 of the second support surface area 24. By varying this total angle, ie the sum of the two angles W ₄ and W ₅ , the geometry of the pyramid-like arrangement can thus be formed at, for example, equal angles W ₂ and W ₃ are influenced by the four support surfaces 28, 30, 32, 34, and in particular a concentration of the forces are supported in the direction of an imaginary pyramid peak.

Due to this angular orientation of the various support surface regions 22, 24 or of their support surfaces 28, 30, 32, 34 and due to the orientation of the attachment shaft 26 with respect to the body region 12, a concentration of the forces introduced in the body region 12 in the milling operation is achieved in such a manner, that lateral forces, which load the transition between the body portion 12 and the attachment shaft 26 to shear, are greatly reduced. This is also helped by the fact that an angle W ₆ formed between the shank longitudinal axis L _B and the longitudinal axis L _{M of} the chisel receiving opening 18 and hence a longitudinal axis of the chisel lies in a range of 12.5 °.

In the FIGS. 9 and 10 a base part 44 which can be used in conjunction with the bit holder 10 described above is shown. The FIGS. 11 and 12 show this base part 44 in assembly with the bit holder 10th

In the base part 44, a fastening shank receiving opening 46 is formed, which is connected both to an in Fig. 9 above recognizable counter-support side 48, as well as in Fig. 10 recognizable connection side 50 of the base part 44 is open. In the region of the connection side 50, the base part 44 is fixed, for example, by welding to a milling drum.

At the counter-support side 48, a first counter-support surface region 52 is formed in association with the first support surface region 22. In association with the second support surface region 24, a second counter-support surface region 54 is formed. The first counter-support surface region 52 comprises a first counter-support surface 56 in association with the first support surface 28 of the first support surface region 22 and comprises a second counter-support surface 58 in association with the second support surface 30 of the first support surface region 22. The second counter-support surface region 54 accordingly in association with the first support surface 32 of the second support surface region 24, a first counter-support surface 60 and comprises in association with the second support surface 34 of the second support surface region 24, a second counter-support surface 62. The respective counter-support surfaces 56, 58, 60, 62 are mutually corresponding the respective Anwinkelungen the support surfaces 28, 30, 32, 34 of the chisel holder 10 is angled to each other and flat, so that the mutually associated support surfaces and counter-support surfaces can abut flat against each other.

Between the first counter-supporting surface 56 and the second counter-supporting surface 58 on the one hand and between the first counter-supporting surface 60 and the second counter-supporting surface 62 on the other hand, in each case a Einsenkungsartiger third transition region 64 and 66 is formed. Similarly, between the two counter-Abstützflächenbereichen 52, 54, ie between the first counter-support surface 56 and the first counter-support surface 60 and the second counter-support surface 58 and the second counter-support surface 62, a Einsenkungsartiger fourth transition region 68, 70 is formed. By means of these, for example, with at least partially rounded contour formed, Einsenkungsartigen transition regions 64, 66, 68, 70 occurring notch stresses are on the one hand at the initiation of milling forces avoided. On the other hand, as the representations of the FIGS. 11 and 12 clearly show in the Einsenkungsartigen transitional areas 64, 66, 68, 76 each made room for the various transition areas of the chisel holder 10, where the support surfaces merge into each other. This ensures that even if wear occurs in the region of the abutting support surfaces or counter-support surfaces, a re-setting and, accordingly, a deeper penetration of the first and second transition regions in the third and fourth transition regions is possible.

One recognizes by means of the Fig. 9 . 11 and 12 it is clear that the support side 20 formed on the bit holder 10 on the one hand and the counter-support side 48 formed on the base part 44 on the other hand are in particular complementarily shaped with the support surfaces or counter-support surfaces coming into abutment with each other. Thus, a plurality of prism-like adjoining support surfaces or counter-support surfaces results in a funnel-like configuration which ensures stable support of the bit holder 10 and base part 44 also in the direction transverse to the attachment shaft 26 or the shaft longitudinal axis L _B. This generally leads to a relief of the mounting shaft 26, in particular in the transverse direction, whereby the risk of breakage of the mounting shaft is significantly reduced.

In addition to the support interaction described in detail above between the bit holder 10 and the base part 44 in the region of the support side 20 and the counter support side 48 in the chisel holder system constructed according to the invention further relief of the mounting shaft 26 by its investment interaction with the base member 44 in the region of its mounting shank receiving opening 46 reached. This aspect and the Abstützaspekt already explained in detail above can already achieve a significant relief or even force distribution on their own. However, they are particularly advantageously realized in combination with one and the same bit holder system.

The attachment shank 26 of the chisel holder 10 has an attachment member application area 76 at a first side located approximately below the first support surface area 22 and has a support area 78 at a second side opposite the shank longitudinal axis L _B. The Befestigungsorganbeaufschlagungsbereich is notched formed with a Befestigungsorganbeaufschlagungsfläche 80, the surface normal F _N with respect to the shaft longitudinal axis L _B at a relatively small angle W ₇ of about 62.5 ° is inclined. As a result, a fastening element 82 provided on the base part, whose longitudinal center axis is oriented approximately parallel to the surface normal F _N , that is substantially orthogonal to the fastening element loading surface 80, generates a force component directed comparatively strongly in the direction of the shank longitudinal axis L _B when the fastening shank 26 is acted on. It should be noted here that the attachment member 82 is received in a Befestigungsorganaufnahmeöffnung 84 of the base member 44 which is at least partially formed with internal thread, so that at least partially formed with Au-ßengewinde corresponding attachment member 82 by rotation, so screwing in the direction of a Fastener receiving hole _longitudinal axis L _{O can be} moved toward the Befestigungsorganbeaufschlagungsfläche 80 to and away from it.

Due to the above-mentioned geometric relationships, the Befestigungsorganaufnahmeöffnungslängsachse L _O to a Befestigungsschaftaufnahmeöffnungslängsachse L _A , which in the assembled state, at least in terms of their orientation also substantially coincides with the shaft longitudinal axis L _B , at the angle W ₇ of about 62.5 °.

If the fastening member 82 is moved by screwing into the Befestigungsorganaufnahmeöffnung 84 and pressed against the Befestigungsorganbeaufschlagungsfläche 80, the fastening shaft 26 is pressed with its support portion 78 against a counter-support portion 86 of the base member 44. The support region 78 is formed with two support surface regions 88, 90, which run with respect to each other angled or inclined, in particular each have a preferably circular curved course in the circumferential direction about the shaft longitudinal axis L _B. In a central region of the support region 78, these two support surface regions 88, 90 adjoin one another in a fifth transition region 92. This fifth transition region 92 is formed like a depression, preferably with in the direction of the shaft longitudinal axis L _B extending, concave depression profile.

It can clearly be seen that the support surface regions 88, 90 of the support region 78 are designed so that they project radially beyond the base outer peripheral surface 94 of the attachment shaft 26 with respect to the attachment shank longitudinal axis L _B. The embodiment is such that this radial projection in the central region of the support region 78, ie where the fifth transition region 92 is formed, is the lowest, so there, for example, almost no radial projection is present, while in the circumferential direction and in the direction of the fifth Transition region 92 away this radial projection increases. In particular, it can be seen that both at the axial end regions of the support surface regions 88, 90, as well as in the circumferential direction of the fifth transition region 92 remote end regions each have a step-like, possibly slightly curved transition to the base outer peripheral surface 94 of the mounting shaft 26 is present.

By the configuration of the mounting shaft 26 in the manner described above, this is supported when acted upon by the Beaufschlagungsorgan 82 in two with respect to the holder center plane laterally lying surface areas, namely substantially with the support surface areas 88, 90, on the base part 44 from. This leads to a pressure distribution and to avoid a line-like support contact in the peripheral center of the support region 78. In particular, due to the recess-like fifth transition region 92, care is taken that no or only small forces are transmitted between the attachment shaft 26 and the base part 44 in this center of the support region 78 become.

A further significant advantage of the support surface regions 88, 90 projecting radially beyond the base outer peripheral surface 94 is that locally localized surface regions are utilized there to generate abutting contact between the attachment shaft 26, ie the bit holder 10, and the base part 44. Since both the bit holder 10 and the base member 44 are generally provided as forgings and therefore those surfaces in which a mutual support, to achieve the required precision material to be edited or reworked, this operation can be limited to the fact actually provided surface areas, namely where the support surface areas 88, 90 are formed.

Corresponding to the support region 78 on the attachment shank 26, the counter-support region 86 is formed on the base part 44. The counter-support region 86, in association with the support surface regions 88, 90, has counter-support surface regions 96, 98. These adjoin one another in a sixth transition region 100, wherein the sixth transition region 100 is formed like a projection, preferably with a convexly curved projection 102 elongated in the direction of the fastening shaft receiving aperture longitudinal axis L _A. This can be provided for manufacturing reasons by an insert part 104 which is inserted into a corresponding opening 106 of the base part, for example, is inserted under press fit and protrudes with a peripheral region thereof for providing the projection 102 radially inwardly beyond the two counter-Abstützflächenbereichen 96, 98.

The counter-supporting surface portions 96, 98 are formed in the fixing shaft receiving opening 46 so as to protrude radially inwardly of the fixing shaft receiving opening longitudinal axis L _A at least in regions via a base inner peripheral surface 108 of the fixing shaft receiving opening 46. The configuration may be such that near the sixth transition region 100 this radial projection is maximum and decreases in the circumferential direction in the direction away from the sixth transition region 100, so that gradually the counter-support surfaces 96, 98 are transferred into the basic inner circumferential surface 108. Just as in the embodiment of the fastening shaft 26 or the support region 78, a restriction of the surface areas to be machined to provide a precise abutment contact on the counter-Abstützflächenbereiche 96, 98 is reached, in particular in their two axial end portions again like a step or curvature in the basic inner peripheral surface 108 on the base part 44 can pass.

Corresponding to the inclination of the two support surface regions 88, 90 with respect to each other, the two counter-support surface regions 96, 98 are inclined with respect to each other, in this case with a curved course, this curvature being able to correspond to the curvature of the two support surface regions 88, 90 in order to achieve a large contact area. Since the support surface areas 88, 90 as well as the counter-support surface areas 96, 98 protrude only in a peripheral area over the base outer peripheral surface 94 and the basic inner peripheral surface 108, the attachment shaft 26 can be introduced into the attachment shaft receiving opening 46 with lateral play in principle, it is only by moving the attachment member 82 onto the attachment member loading surface 80 that a firm abutting contact is created between the support surface portions 88, 90 and the counter support surface portions 96, 98. A leading to a stronger pressure contact of the two transition regions 92, 100 is thereby avoided. Their functionality lies essentially in Already during the insertion movement of the chisel holder 10 into the base part 44 before the support side 20 and the counter-support side 48 become centering effect, to achieve a defined orientation of the chisel holder 10 with respect to the base part 44.

To the very uniform force distribution in the support of the mounting shaft 26 at the counter-support portion 86 also contributes that both the support portion 78, and the counter-support portion 86 to the holder center plane or a plane corresponding to this plane of symmetry of the base member 44 symmetrical, in particular point-symmetrical, are formed.

Due to the configuration of the bit holder and the base part on the support side and the counter-support side and in the support area or in the counter-support area with the different Abstützflächenbereichen and Gegen-Abstützflächenbereichen a defined positioning of the Mei-ßelhalters while relieving the bit holder especially in the area reached the attachment. Contributing to this is that the load distribution on a plurality of mutually defined Abstützflächenbereichen or support surfaces and counter-Abstützflächenbereichen or counter support surfaces vorgsehen is in which the bit holder and the base part directly abutting each other. This means that, in the sense of the present invention, a supporting surface area or counter-supporting surface area with the respective surfaces serving for mutual support is designed or processed in such a way that a direct metal-metal contact can be generated. Since both the base part and the chisel holder are generally produced as forgings, the surfaces serving as support surface areas or counter-support surface areas in the context of the present invention are thus basically manufactured and / or reworked in terms of materials. In this way, the high precision required for a substantial relief and accurate positioning of these surfaces can be ensured, which would not be feasible in a merely machined in a forging surface.

To assemble the above-described system, the bit holder 10 with its attachment shank 26 is inserted into the stub shaft 10 provided in the base member 44 Befestigungsschaftaufnahmeöffnung 46 at on a rotatable milling drum fixed by welding, until the two Abstützflächenbereiche 22, 24 of the bit holder 10 in contact with the respective associated counter-Abstützflächenbereichen 52, 54 of the base part come. Then, for example, the screw-like fastening member 82 is tightened so that it is further moved into the Befestigungsorganaufnahmeöffnung 84 and pressed against the Befestigungsorganbeaufschlagungsfläche 80 on the mounting shank 26. As a result, on the one hand, a stable system interaction between the support surface regions 22, 24 and the counter-support surface regions 52, 54 is achieved. On the other hand, a stable contact of the support region 78 or of the two support surface regions 88, 90 thereof on the counter-support region 86 or the two counter-support surface regions 96, 98 is achieved.

Since not only the chisel held in the chisel holder 10 wear during operation of a milling machine, but also wear in the field of chisel holder 10, by reversing the process described above, ie by removing the fastener 82 from the mounting shank 26 and pulling out the chisel holder 10 and of the mounting shaft 26 thereof, a worn blade holder 10 is removed from the base member 44 and replaced with a new bit holder or a less worn bit holder. This is used in the manner described above with its mounting shank 26 in the associated attachment shank receiving opening 46 in the base member 44 and fixed to the attachment member 82. This process can then be repeated several times with recurring wear then, of course, in conjunction with the same set on a milling drum base part. If wear also occurs in the area of a base part, then of course this can also be done by a milling drum be solved by separating the holding this welding connection and replaced by a new base part.

Claims (16)

1. A chisel holder, comprising:

   - a body region (12) having a chisel-receiving opening (18) which is open at least toward a chisel insertion side (14) of the body region (12),

   - a fastening shank (26) which extends from a supporting side (20) of the body region (12) with a shank longitudinal axis (L_B),

   wherein the body region (12) has, on its supporting side (20), a first supporting surface region (22) and a second supporting surface region (24) which is angled in relation to the first supporting surface region (22), wherein the chisel-receiving opening (18) is open toward that supporting side (20) substantially in the region of the first supporting surface region (22) and wherein the fastening shank (26) extends from the body region (12) substantially in the region of the second supporting surface region (24),
   characterized in that
   the second supporting surface region (24) comprises a first supporting surface (32) and a second supporting surface (34) which is angled in relation to the first supporting surface (32) and
   in that the first supporting surface region (22) comprises a first supporting surface (28) and a second supporting surface (30) which is angled in relation to the first supporting surface (28).
2. The chisel holder as claimed in claim 1
   characterized in that the first supporting surface (28, 32) and the second supporting surface (30, 34) of the first supporting surface region (22) or/and of the second supporting surface region (24) are arranged substantially symmetrically with respect to a holder central plane.
3. The chisel holder as claimed in claim 1 or 2,
   characterized in that

   - a first angle (W₁) enclosed between the first supporting surface (28) or/and the second supporting surface (30) of the first supporting surface region (22) and the second supporting surface region (24) lies in the range of 127° to 147°, and is preferably approximately 137°,
   or/and

   - a second angle (W₂) enclosed between the first supporting surface (28) and the second supporting surface (30) of the first supporting surface region (22) lies in the range of 120° to 140°, and is preferably approximately 130°, or/and

   - a third angle (W₃) enclosed between the first supporting surface (32) and the second supporting surface (34) of the second supporting surface region (24) lies in the range of 100° to 120°, and is preferably approximately 110°, or/and

   - an angle (W₄+W₅) enclosed between a transition region (41) between the first supporting surface (28) and the second supporting surface (30) of the first supporting surface region (22) and a transition region (40) between the first supporting surface (32) and the second supporting surface (34) of the second supporting surface region (24) lies in the range of 121 ° to 141°, and is preferably approximately 131 °.
4. The chisel holder as claimed in one of claims 1 to 3,
   characterized in that at least one supporting surface (28, 30) of the first supporting surface region (22) and the second supporting surface region (24) adjoin one another in a first transition region (36, 38) which extends in a linear or/and straight fashion.
5. The chisel holder as claimed in one of claims 1 to 4,
   characterized in that the first supporting surface (32) and the second supporting surface (34) of the second supporting surface region (34) adjoin one another in a second transition region (40) which extends in an areal or/and straight fashion.
6. The chisel holder as claimed in claim 2 and 5,
   characterized in that the second transition region (40) comprises a transition surface (42) which is substantially orthogonal with respect to the holder central plane.
7. The chisel holder as claimed in one of claims 1 to 6,
   characterized in that a longitudinal central axis (L_M) of the chisel-receiving opening (18) and the shank longitudinal axis (L_B) are inclined relative to one another at an angle (W₆) of 10° to 15°, preferably approximately 12.5°.
8. The chisel holder as claimed in one of claims 1 to 7,
   characterized in that a fastening element loading region (76) having a fastening element loading surface (80) is provided on the fastening shank (26), and in that the shank longitudinal axis (L_B) and a surface normal (F_N) of the fastening element loading surface (80) are inclined relative to one another at an angle (W₇) of 50° to 65°, preferably approximately 62.5°.
9. The chisel holder as claimed in one of claims 1 to 8,
   characterized in that an angle of inclination (W₄) of the shank longitudinal axis (L_B) relative to the first supporting surface region (22) and an angle of inclination (W₅) of the shank longitudinal axis (L_B) relative to the second supporting surface region (24) are substantially identical to one another.
10. A chisel holder system, comprising:

    - a chisel holder (10) as claimed in one of the preceding claims,

    - a base part (44), having a first counterpart supporting surface region (52) for supporting the first supporting surface region (22),
    characterized

    - by a second counterpart supporting surface region (54), which is angled relative to the first counterpart supporting surface region (52), for supporting the second supporting surface region (24),
    or/and

    - in that the first counterpart supporting surface region (52) comprises a first counterpart supporting surface (56) for supporting the first supporting surface (28) of the first supporting surface region (22) and a second counterpart supporting surface (58), which is angled relative to the first counterpart supporting surface (56), for supporting the second supporting surface (30) of the first supporting surface region (22).
11. The chisel holder system as claimed in claim 10,
    characterized in that the angle of the first supporting surface region (22) relative to the second supporting surface region (24) and the angle of the first counterpart supporting surface region (52) relative to the second counterpart supporting surface region (54) or/and the angle of the first supporting surface (28) relative to the second supporting surface (30) of the first supporting surface region (22) and the angle of the first counterpart supporting surface (56) relative to the second counterpart supporting surface (58) of the first counterpart supporting surface region (52) are complementary to one another.
12. The chisel holder system as claimed in claim 10 or 11,
    characterized in that the second counterpart supporting surface region (54) comprises a first counterpart supporting surface (60) for supporting the first supporting surface (32) of the second supporting surface region (24) and a second counterpart supporting surface (62), which is angled relative to the first counterpart supporting surface (60), for supporting the second supporting surface (34) of the second supporting surface region (24).
13. The chisel holder system as claimed in claim 12,
    characterized in that the angle of the first supporting surface (32) relative to the second supporting surface (34) of the second supporting surface region (24) and the angle of the first counterpart supporting surface (60) relative to the second counterpart supporting surface (62) of the second counterpart supporting surface region (54) are complementary to one another.
14. The chisel holder system as claimed in one of claims 10 to 13,
    characterized in that the first counterpart supporting surface (56, 60) and the second counterpart supporting surface (58, 62) of at least one counterpart supporting surface region (52, 54) adjoin one another in a depression-like third transition region (64, 66).
15. The chisel holder system as claimed in one of claims 10 to 14,
    characterized in that the first counterpart supporting surface region (52) and the second counterpart supporting surface region (54) adjoin one another in a depression-like fourth transition region (68, 70).
16. The chisel holder system as claimed in one of claims 10 to 15,
    characterized in that a fastening shank receiving opening (46) having a fastening shank receiving opening longitudinal axis (L_A) and a fastening element receiving opening (84) which is open toward the fastening shank receiving opening (46) and which has a fastening element receiving opening longitudinal axis (Lo) are provided in the base part (44), and in that the fastening shank receiving opening longitudinal axis (L_A) and the fastening element receiving opening longitudinal axis (Lo) are inclined relative to one another at an angle (W₇) of 50° to 65°, preferably approximately 65°.

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