DE102011051520A1 - Bit holder for road milling machine, has support body comprising tilling side, which is turned toward projection and comprises bit retainer, and body surfaces diverging from projection side in direction to tilling side - Google Patents

Abstract

The holder (20) has a support body (21) at which a plunging projection is directly or indirectly connected at a plunging projection side. The body has two erosion surfaces, which stay together at an angle. The body comprises a tilling side, which is turned toward the projection. The tilling side comprises a bit retainer (27) i.e. through-hole. The surfaces diverge from the projection side in a direction to the tilling side. A longitudinal axis of the projection and a middle longitudinal axis of prisms formed by the erosion surfaces have an angle at range between 100 and 130 degrees.

Description

The invention relates to a bit holder for a tillage machine, in particular a road milling machine, a mining machine or the like, with a support body to which a plug-in approach is directly or indirectly connected to a plug approach side, wherein the support body has two first and / or two second Abtragflächen to each other are at an angle, and wherein the support body has a processing side having a chisel receptacle.

From the US 3,992,061 is a chisel holder is known, which forms a support body with a one-piece molded plug neck. In this case, the support body is penetrated by a cylindrical bore formed as a chisel. In the chisel holder, a machining tool, in this case a round shank chisel, are used. The support body has two mutually angled Abtragflächen, which serve to support on corresponding support surfaces of a base part. The base part has a plug-in receptacle into which the bit holder with its plug-in extension can be inserted interchangeably. In the assembled state, the removal surfaces of the chisel holder abut against the support surfaces of the base part. In order to maintain a fixed area allocation, a clamping screw is used, which jams the insertion lug in the socket of the base part.

During machining operation, the machining tool engages in the substrate to be processed. This high transfer forces are transmitted. These are transferred from the machining tool to the bit holder. There they are passed on via the Abtragflächen in the base part.

During the machining engagement, the force direction and also the amount of force varies under otherwise identical conditions, solely due to the fact that the machining tool forms a chip (commaspan) thickening from the entry point to the exit point. In addition, the direction of force and the amount varies depending on various parameters such as the milling depth, the feed, the material to be processed, etc .. The in the US 3,992,061 shown embodiment of a chisel holder can not dissipate the processing forces, especially at high feed speeds with sufficiently good service life. In particular, the wear surfaces strike fast. In addition, the plug-in approach is exposed to high bending stresses and there is a risk that after a component fatigue a plug neck breakage occurs.

From the DE 34 11 602 A1 Another chisel holder is known. This has a support body which is supported by projections on a base part. On the support body, a clamping part is formed, which can be clamped via wedge joints with the base part.

The US 4,828,327 shows a chisel holder, which is designed as a solid block and is penetrated by a chisel holder. Furthermore, the bit holder has a threaded receptacle which is in alignment with a screw receptacle of a base part. Through the screw holder, a fastening screw can be passed and screwed into the threaded receptacle of the chisel holder. When tightening the mounting screw of the bit holder is pulled into an L-shaped recess of the base part and supported there on support surfaces.

The above-described bit holder are usually arranged projecting on the surface of a Fräswalzenrohres. During machining operation, lateral forces also occur which act transversely to the tool feed direction. These lateral forces can be combined with those in the US 4,828,327 described chisel holders are not always sufficiently stable recorded. In particular, these transverse forces are transferred into the fastening screw, which is then subjected to strong shear.

It is an object of the invention to provide a bit holder of the type mentioned above, which is characterized by increased stability.

This object is achieved in that the first and / or second removal surfaces diverge from the insertion side in the direction of the processing side. The removal surfaces thus form a prism-shaped support in the region of the insertion side and allow here a reliable power transmission from the bit holder on the base part. This direct support also reduces the load on the plug-in projection during the machining operation. The arrangement of the removal surfaces according to the invention also takes into account the force curve which typically varies with tillage tools, so that overall a longer service life can be achieved.

According to a preferred embodiment of the invention, it may be provided that the surface normals of the first and / or second removal surfaces point in each case to their bit holder side viewed in the tool advance direction. Accordingly, therefore, the removal surfaces are arranged, for example when using the bit holder on a Fräswalzenrohr inclined to the axis of rotation of the Fräswalzenrohres. By this arrangement can also reliably lateral forces, during the Processing application arise, be collected, which leads to a further optimization of the service life.

Particularly preferably, the first and / or second removal surfaces include an obtuse angle, in particular in the range between 100 ° and 140 °. This angular arrangement guarantees that the bit holder can easily be inserted in confusing areas and in rough construction site operation in a base part, so that a reliable assignment of the Abtragflächen is guaranteed to the support surfaces of the base part. In addition, it is prevented that even after a long period of use in which, if necessary, the Abtragflächen work off a bit far from the support surfaces, jamming occurs. Thus, the chisel holder can always be changed easily. In addition, this angular employment of the first and / or second removal surfaces guarantees reliable removal of the machining forces. In this case, the opening angle depicts the wide range of directions from which the transverse forces can act in the course of the tool engagement and by changes in the other parameters.

If this angle range between the first removal surfaces is particularly preferably between 100 ° and 120 ° and / or the angular range between the second removal surfaces is between 120 ° and 140 °, then the tool system is designed in an optimized way for use in road milling applications and the loading conditions occurring thereby ,

An inventive bit holder can be designed such that the removal surfaces are at least partially interconnected via a transitional section in the region of the plug approach side. Accordingly, the ablation surfaces do not hit each other at the angle vertex, so that no sharp-edged angle transition occurs, which can be damaged. In addition, a Nachsetzbereich be created with the transition section and in conjunction with the base part. Accordingly, when the removal surfaces and / or the support surfaces of the base part work off, the bit holder can be continuously inserted into this adjustment space, wherein the removal surfaces always remain applied to the support surfaces. In particular, the plane-surface system remains intact even if, when the base part of the chisel holder must be replaced with a new and that several times.

Particularly preferably, the plug-in approach is at least partially connected in the area of the removal surfaces to the plug-in side. This allows a direct assignment of the removal surfaces to the insertion projection, which leads to a smaller component size and, moreover, offers an optimized force flow.

A bit holder according to the invention may be characterized in that the longitudinal axis of the plug attachment and the central longitudinal axis of the prisms formed by the first or second removal surfaces enclose an angle in the range between 100 ° and 130 °. Again, an optimal power flow is achieved by this design feature.

It is also conceivable for the first removal surfaces in the feed direction to be arranged at least in regions in front of the insertion projection and the second removal surfaces in the feed direction at least in regions behind the insertion projection. This design takes into account in particular the varying force curve during the machining operation, and the plug-in shoulder is further relieved of machining forces.

Preferably, it is provided that the first removal surfaces at least partially form the underside of a front apron. The front apron usually covers a front portion of the base part, thus protecting it from wear. The fact that now the front apron is also used for attaching the Abtragflächen results in a compact design, and it can be the chisel holder easy to manufacture.

It can also be provided that the second removal surfaces at least partially form the underside of a rear support lug. In this case, under certain conditions of use on the rear support approach a large part of the forces transmitted. In a construction which provides a chisel holder, for example a bore, for receiving a machining tool, in particular a round shank chisel, on the chisel holder, it is optimally provided that the central longitudinal axis of the chisel holder is arranged at least in regions between the ablation surfaces. Thus, on the one hand, a good force distribution of the machining forces introduced via the machining tool can be achieved on both removal surfaces. Furthermore, the bit holder can also be positioned in a different orientation to a Fräswalzenrohr, while maintaining the reliable power transmission is maintained.

It has been found that an optimal force distribution of the forces to be removed in longitudinal and transverse forces is achieved if it is provided that the angle between the central longitudinal axis of the prism of the first Abtragflächen and the central longitudinal axis of the bit holder in the range between 40 ° and 60 °, particularly preferably between 45 ° and 55 °, and / or that the angle between the central longitudinal axis of the prism of the second removal surfaces and the central longitudinal axis of the bit holder is in the range between 70 ° and 90 °, more preferably between 75 ° and 85 °. These angular positions also guarantee that the chisel holder due to the employment of the removal surfaces does not reach too large a width, and thus a material-optimized construction is guaranteed.

According to a further embodiment variant of the invention, it may be provided that the bit receptacle merges into a flushing channel, and that the flushing channel emerges at least in regions in the region between the second removal surfaces. The flushing channel is thus arranged so that the wear surfaces do not hit each other pointedly.

Particularly preferably, the first and the second removal surfaces each form a Abtragflächenpaar, wherein the Abtragflächen are each made V-shaped. By the V-shaped employment of Abtragflächen prisms are formed in the sense of Werkzeugvorrichtungsbaus. These two prisms guarantee a stable support of the chisel holder against the base part. The prisms formed by the first and second removal surfaces have a central longitudinal axis. This central longitudinal axis lies in the bisecting plane which is formed between the two removal surfaces.

If it is additionally provided that in each case a first removal surface of the first Abtragflächenpaares and a second wear surface of the second Abtragflächenpaares at an angle, preferably in the range between 120 ° and 160 °, employed, and the Abtragflächenpaare form a support region, then the bit holder in a likewise correspondingly designed angular bit holder receptacle of the base part is used and stably supported therein. A corresponding arrangement applies to the remaining surfaces of the first and second Abtragflächenpaares, d. H. The two prisms are set at an angle to each other and in turn form a prism. The opening angle reflects the wide range of directions from which the longitudinal forces can act in the course of the tool engagement and changes in the other parameters.

Furthermore, it is conceivable that the central longitudinal axis of the plug-in approach is in the angular range of -10 ° to + 10 ° to the bisector of the first and / or second Abtragflächenpaares. Thus, a uniform bias is applied during bracing of the chisel holder with the base part. Particularly preferably, it is provided that the central longitudinal axis of the plug-in projection is in the angular range of -2 ° to + 2 ° to the bisector of the first and / or second Abtragflächenpaares.

An inventive bit holder can also be characterized in that the surface normals of the first and / or second removal surfaces are inclined to the feed direction, so that transverse forces are reliably transferable.

A particularly preferred embodiment of the invention is such that a plane receiving the bisecting line is arranged between the first and / or the second removal surfaces, and that the insertion projection is arranged symmetrically with respect to this plane. As a result of this symmetrical design, the bit holder can also be mounted on various mounting positions of a milling drum tube or the like, or this has the advantage that only one variant is required and does not have to work with left and right bit holders.

In order to relieve the plug-in projection and to protect it from fatigue fractures, it is provided according to a variant of the invention that the connection region of the insertion projection is arranged on the support body at least 80% in the region of the Abtragflächenpaares formed by the first Abtragflächenpaares.

The invention will be explained in more detail below with reference to an embodiment shown in the drawings. Show it:

1 a combination of a base part and a chisel holder in a perspective side view;

2 the representation according to 1 in exploded view;

3 the chisel holder according to 1 and 2 in front view;

4 the chisel holder according to 1 to 3 in rear view;

5 the chisel holder according to 1 to 4 in side view from the left;

6 the representation according to 5 in a vertical section through the central transverse plane of the chisel holder;

7 the chisel holder according to 1 to 6 in side view from the right and partly in section;

8th one in 5 with VIII-VIII marked cutting course;

9 one in 7 IX-IX marked sectioning;

10 one in 7 with XX marked cutting course;

11 the tool combination according to 1 in plan view;

12 one in 11 XII-XII marked sectioning;

13 according to the chisel holder 5 in front view;

14 the chisel holder in view from behind; and

15 the chisel holder in a rotated side view.

1 shows a tool combination consisting of a base part 10 and a chisel holder 20 , Here is the chisel holder 20 interchangeable with the base part 10 connected. The base part 10 has a massive body 13 on, which is a lower connection side 11 having. This connection side 11 is curved concave, the curvature is selected according to the outer diameter of a Fräswalzenrohres. This can be the base part 10 with its connection side 11 placed on the outside of the Fräswalzenrohres and are welded to this. The main body 13 has a projection on the front, the side of inclined surfaces 14 and front of incline surfaces 15 is limited. The slope surfaces 15 are set at an angle to each other and the inclined surfaces 14 Angled close to the slope surfaces 15 at. This results in front of an arrow-shaped geometry of the base part 10 leading to a better clearing action of the base part 10 leads.

As the 2 clarifies, is in the base part 10 a chisel holder holder 16 with a plug-in receptacle 16.7 incorporated. This penetrates the plug-in receptacle 16.7 the main body 13 completely and thus flows into the connection side 11 , In the base part 10 is a threaded receptacle 18 incorporated in the plug-in receptacle 16.7 flows (see 12 ). The chisel holder holder 16 has first support surfaces 16.1 and second support surfaces 16.2 on. The first supporting surfaces 16.1 form a first support surface pair and the second support surfaces 16.2 form a second support surface pair. Here are the support surfaces in each support surface pair 16.1 . 16.2 each arranged at an angle to each other. Furthermore, the support surfaces are 16.1 each to the support surfaces 16.2 Angled so that an obtuse chisel holder recording 16 results. In the transition area between the individual support surfaces 16.1 and 16.2 are each Nachsetzräume 16.3 . 16.4 . 16.5 provided in the form of recesses. In the area of Nachsetzraumes 16.5 is still a recess 16.6 provided a transition from the bit holder holder 16 to the thread receiving 18 creates.

As 2 is further to recognize the entry into the threaded receptacle 18 an area 17 formed laterally bounded by inclined surfaces, wherein the inclined surfaces diverging to the back of the base part 10 open. In this way, an easy cleanability of the surface 17 and thus a tool holder 43 a pressure screw 40 created. The pressure screw 40 has a threaded portion 41 on, with which they are in the threaded receptacle 18 can be screwed. Furthermore, the pressure screw 40 with a pressure approach 42 formed in the form of a truncated cone-shaped pin, which is integral to the threaded portion 41 is formed.

As 2 further shows, can with the base part 10 the chisel holder 20 get connected. The chisel holder 20 has a support body 21 , the front side with an apron 22 Is provided. The skirt 22 carries integrally formed a bridge 22.1 that of the apron 22 ascends upwards. To the support body 21 is also an approach 23 one piece coupled in a cylindrical section 24 concludes. The cylindrical section 24 is provided with wear marks, in the present case as circumferential grooves 26 are formed. The cylindrical section 24 closes with a support surface 25 concentric with the bore entry of a chisel holder 27 circulates. The chisel holder 27 goes over a chamfered insertion section 1.27 in the support surface 25 above.

As 4 shows is the chisel pickup 27 designed as a through hole. The supporting body 21 is provided with a rear recess, which serves as a flushing channel 28 serves. The flushing channel 28 thus opens the chisel holder 27 in the region of their bore outlet radially outward. Thus, during the tool insert in the bit holder 27 occurred Abraumpartikel through the flushing channel 28 be discharged radially outward.

3 lets recognize that the support body 21 in the area of the apron 22 first removal surfaces 29.1 having. These removal surfaces 29.1 are at an obtuse angle ε ₁ to each other (see 13 ) and are over a transitional section 29.2 connected with each other. In this case, the angle ε ₁ corresponds to the first removal surfaces 29.1 the angle between the first support surfaces 16.1 of the base part 10 ,

4 lets recognize that the support body 21 Back facing down second Abtragflächen 29.4 has. The second removal surfaces 29.4 are at an angle ε ₂ to each other (see 14 ), whereby here also the angle ε ₂ between the second removal surfaces 29.4 the angle between the second support surfaces 16.2 of the base part 10 equivalent. While the first ablation surfaces 29.1 by means of the transition section 29.2 merge into each other, is between the second ablation surfaces 29.4 a transition area through the flushing channel 28 and a transition section 29.5 educated.

The removal surfaces 29.1 and 29.4 each form Abtragflächenpaare in the form of a prism. In this case, these prisms have a central longitudinal axis MLL, in the bisecting plane between the two first Abtragflächen 29.1 or the second removal surfaces 29.4 is formed. In the 13 and 14 these bisector levels are marked with WE. The central longitudinal axis is indicated there with MLL, wherein the central longitudinal axis MLL can in principle be located at an arbitrary position within the bisecting plane.

The 3 and 4 show in conjunction with the 13 and 14 that the first ablation surfaces 29.1 and also the second removal surfaces 29.4 diverge from the insertion side towards the machining side. In the present example, the surface normals accordingly converge on the removal surfaces 29.1 . 29.4 from the plug-in side to the machining side. The surface normals thus converge in the region of the tool engagement point, in which the machining forces are introduced into the tool system.

The use of two removal surface pairs with the respective first and second removal surfaces 29.1 respectively 29.4 optimally takes into account the variance of the machining forces during tool engagement. During tool intervention, a commaspan is created. In this chip formation, not only the amount of force, but also the direction of force changes. Accordingly, at the beginning of the tool engagement, the machining force acts in such a way that it tends to pass over that of the first removal surfaces 29.1 derived Abtragflächenpaar is derived. As tool engagement progresses, the direction of the machining force will rotate and then progressively increase over that of the second wear surfaces 29.4 derived Abtragflächenpaar derived. Accordingly, the angle γ '(see 5 ) between the Abtragflächenpaaren so that the variance of the machining force is taken into account, and this processing force always acts in the prisms formed by the Abtragflächenpaaren.

In the 3 and 9 is the central transverse plane MQ of the chisel holder 20 marked. The bit holder is constructed mirror-symmetrically to this median transverse plane MQ, so that it can be installed on a milling drum as a right or left part.

In the 3 and 4 is marked with usual arrow representations the feed direction. The bit holder sides are arranged transversely to the feed direction.

The surface normals of the removal surfaces 29.1 and 29.4 Thus, each point to their seen in the tool feed direction side of the bit holder and down, as shown in the 3 and 4 becomes clear. In 5 this fact is again shown in side view.

However, the processing power does not work only in the direction of the image plane 5 but also in the transverse direction. These lateral force components are then transmitted via the angled setting (ε _1, ε ₂ ) of the removal surfaces 29.1 . 29.4 ideally intercepted. Since at the beginning of the tool engagement the machining forces scatter less in the transverse direction, the angle ε _{1 can} also be selected smaller than ε ₂ .

5 further shows that to the support body 21 a plug-in approach 30 is integrally formed and a rounding transition 29.3 in the first removal surfaces 29.1 and the second wear surfaces 29.4 passes. Here is the plug-in approach 30 arranged so that it substantially, in this case about 90%, in the region of the first ablation surfaces 29.1 to the support body 21 followed. The plug-in approach 30 carries two contact surfaces at the front 31.1 , These are how 3 can recognize, designed as a convex curved cylindrical surfaces. The contact surfaces 31.1 extend longitudinally and parallel to the central longitudinal axis M (s. 5 ) of the plug-in approach 30 , The contact surfaces 31.1 are therefore also parallel to each other. The contact surfaces 31.1 are in the circumferential direction of the plug-in approach 30 spaced apart. They have the same radius of curvature and are arranged on a common pitch circle. The curvature radius corresponds to half the circle diameter. In the area between the contact surfaces 31.1 is a recess 31.2 provided, with the contact surfaces 31.1 parallel to the recess 31.2 run. The recess may have a variety of shapes, for example, be a simple Anspiegelung. In the present embodiment, the recess forms 31.2 a monotony, the concave between the contact surfaces 31.1 is tolerated. The concavity is designed so that there is a part-cylindrical geometry. The recess 31.2 does not extend over the entire length of the plug-in approach 30 but only over a subsection, like this 13 lets recognize. The recess 31.2 is to the free end of the plug-in approach 30 , ie in the plug-in direction, open. The recess 31.2 opens also undercut radially outward. The contact surfaces 31.1 opposite to the plug-in approach 30 at the back a pressure screw holder 32 on that with a printing surface 32.1 equipped.

6 and 9 illustrate that the recess 31.2 between the two contact surfaces 31.1 has a concave vaulted geometry, and in particular can form a partially cylindrical cross-section.

In the 7 to 10 is the design of the plug-in approach 30 in more detail. 9 clearly shows the concave curvature of the recess 31.2 attached to the convex abutment surfaces 31.1 followed. Out 10 it becomes clear that the plug-in approach 30 in his to the contact surfaces 31.1 subsequent region has substantially a circular or oval cross-sectional configuration. 8th illustrates the area of the pressure screw receptacle 32 , where the pressure surface 32.1 at an angle δ to the central longitudinal axis M of the plug-in approach 30 is employed. In this case, this angle of attack δ is preferably in the range between 20 ° and 60 °, to an optimum catchment effect of the chisel holder 20 to reach.

7 further shows that the printing surface 32.1 from the connection area of the plug-in extension 30 to the support body 21 is arranged spaced by the distance measure A.

The contact surfaces 31.1 are by the distance B from the terminal portion of the plug-in approach 30 to the support body 21 spaced apart. The centroid of the contact surfaces 31.1 is the distance C from the centroid of the printing surface 32.1 spaced apart.

For mounting the chisel holder 20 in the base part 10 becomes the plug-in approach 30 in the plug-in receptacle 16.7 plugged in. The insertion movement becomes with the first and second wear surfaces 29.1 . 29.4 limited to the first and second support surfaces 16.1 . 16.2 attacks.

As the 1 and 12 let it be known, the assignment is made so that the transition section 29.2 over the Nachsetzraum 16.4 stands, the Nachsetzraum 16.5 from the transition section 29.5 is bridged and the lateral Nachsetzräume 16.3 are bridged by the angle range between the first and second wear surfaces 29.1 . 29.4 is formed. About the spacing of the chisel holder 20 in the area of these Nachsetzräume 16.3 . 16.4 . 16.5 is achieved that during the machining operation of the bit holder 20 in the Nachsetzräume 16.3 . 16.4 . 16.5 can resume when the erosion surfaces 29.1 . 29.4 and / or the support surfaces 16.1 . 16.2 work off. This is especially true when worn bit holder 20 with existing base part 10 be exchanged for new ones. To fix the prescribed state of installation, the pressure screw 40 in the threaded socket 18 screwed. Here, the pressure paragraph presses 42 with its flat end face on the printing surface 32.1 and thus causes a pull-in force in the direction of the central longitudinal axis M of the plug-in approach 30 acts. At the same time, however, is the pressure screw 40 at an angle to the central longitudinal axis M of the plug-in approach 30 employed that also acting in the direction of the front clamping force in the plug-in approach 30 is introduced. This clamping force is over the contact surfaces 31.1 in the corresponding concave counter surface of the cylindrical portion of the plug receptacle 16.7 transfer. The spacing of the contact surfaces 31.1 over the recess 31.2 guaranteed that the plug-in approach 30 over the two laterally through the contact surfaces 31.1 formed support areas is reliably fixed. This will be especially about the two contact surfaces 31.1 the occurring surface pressures kept low, resulting in a reliable fixation of the plug-in approach 30 leads.

Because of the bit holder 20 in case of wear in the Nachsetzräume 16.3 . 16.4 . 16.5 can be adjusted, an effective wear compensation can be made, with the wear surfaces 29.1 . 29.4 the support surfaces 16.1 . 16.2 overhang at any point, so in case of wear anyway the support surfaces 16.1 . 16.2 be worn evenly without creating a so-called beard or burr. This embodiment is particularly advantageous if the base part 10 As is commonly required, has a life that includes several lifecycles of chisel holders 20 ongoing. Unused chisel holder 20 can then always on a partially worn base part 10 be securely braced and held. Thus, the repair of a machine, in which the base part 10 and chisel holder 20 formed tool system is used, easy. Typically, a variety of tooling systems are mounted on such a machine, such as a road milling machine or a surface miner. In this case, the base part is usually welded on the surface of a Fräswalzrohrs. If now all or some of the chisel holder 20 worn, you can easily against new unworn or teilverschlissene chisel holder 20 (which can be used for example for rough finishing work) are exchanged.

When replacing, first the pressure screw 40 solved. Then the worn chisel holder 20 with its plug-in approach 30 from the plug-in receptacle 16.7 of the base part 10 pulled out and removed. Subsequently, the new (or partially worn) chisel holder 20 with his plug-in projection 30 in the plug-in receptacle 16.7 of the base part 10 used. Now the pressure screw 40 if necessary be replaced by a new one. It then becomes the base part 10 screwed in and in the manner described above with the bit holder 20 braced.

12 lets recognize that the base part 10 a lead 50 carries in the plug-in receptacle 16.7 protrudes. This lead 50 In this case, it is formed by a cylindrical pin, that of the connection side 11 forth in a part-cylindrical recess 19 is driven. The partially cylindrical recess 19 surrounds the cylinder pin, by more than 180 ° of its circumference, so that it is held captive. The in the chisel holder 27 projecting portion of the cylinder pin engages in the recess 31.2 between the contact surfaces 31.1 one. When inserting the plug-in extension 30 in the plug-in receptacle 16.7 threads the lead 50 in the to the free end of the plug-in approach 30 open recess 31.2 reliable. This will be an alignment of the chisel holder 20 opposite the base part 10 reached. This alignment guarantees that now the first and second wear surfaces 29.1 . 29.4 precisely fitting to the system on the supporting surfaces 16.1 . 16.2 come so that a wrong assembly is excluded. Furthermore, prevents the projection 50 and the geometrically adapted recess 31.2 in the form of a key-lock principle that inadvertently a wrong chisel holder 20 at the base part 10 is installed.

The following will be even closer to the angle relationships of the chisel holder according to the invention 20 received.

5 lets realize that the central longitudinal axis 24.1 the chisel pickup 27 at an angle α or φ to the longitudinal orientation of the transition section 29.2 respectively 29.5 and thus also to the central longitudinal axis MLL of the first Abtragflächen 29.1 or from the second removal surfaces 29.4 formed prism is. The angle α can be between 40 ° and 60 ° or φ in the range between 70 ° and 90 °.

5 further shows that in a projection of the ablation surfaces 29.1 and 29.4 in a plane transverse to the feed direction (projection accordingly 5 ) the removal surfaces 29.1 and 29.4 are angled at an angle γ in the range between 40 ° and 60 ° to each other, or that the opening angle between the transition sections 29.2 and 29.5 in longitudinal direction according to 5 between 120 ° and 140 °. Accordingly, the angle γ 'lies between the central longitudinal axes MLL of the two of the removal surfaces 29.1 and 29.4 formed prisms (Abtragflächenpaare) in the range between 120 ° and 140 °. Furthermore stand with such a projection of the removal surfaces 29.1 . 29.4 the first removal surfaces 29.1 at an angle β and the second removal surfaces 29.4 at an angle μ to the central longitudinal axis M of the plug-in approach 30 , The same applies here also for the central longitudinal axes MLL of the prisms. The angles β and μ can be in the range between 100 ° and 130 °, preferably in the range between 110 ° and 120 °.

13 shows that the first ablation surfaces 29.1 include an angle ε ₁ . Preferably, this angle ε _{1 should be} in the range between 100 ° and 120 °. The bisector of this angle ε ₁ lies in a plane and 13 clarifies that the plug-in approach 30 is arranged symmetrically to this plane.

In the same way, the rear second ablation surfaces 29.4 in accordance with each other at an angle ε ₂ employed as this 14 shows. However, the angle ε _{2 may} deviate from the angle ε ₁ and, in the present embodiment, lie between 120 ° and 140 ° and the plug-in projection 30 is also arranged symmetrically to the bisector plane of this angle ε ₂ and equipped.

15 shows that in each case a first erosion surface 29.1 of the first Abtragflächenpaars and a second Abtragfläche 29.4 of the second Abtragflächenpaars are set to each other at an angle ω and form a support area.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 3992061 [0002, 0004]
• DE 3411602 A1 [0005]
• US 4828327 [0006, 0007]

Claims (19)

Chisel holder for a soil cultivating machine, in particular a road milling machine, with a supporting body ( 21 ), to which directly or indirectly a plug-in extension ( 30 ) is connected to a plug-in side, wherein the support body ( 21 ) two first and / or two second removal surfaces ( 29.1 . 29.4 ), which are at an angle to each other (ε ₁ , ε ₂ ), and wherein the support body ( 21 ) has a processing side facing away from the insertion projection, which has a chisel holder ( 27 ), characterized in that the first and / or second removal surfaces ( 29.1 . 29.4 ) diverge from the plug-in side toward the machining side. Chisel holder according to claim 1, characterized in that the surface normals of the first and / or second removal surfaces ( 29.1 . 29.4 ) in each case to their in the tool feed direction (v) seen bit holder side have. Chisel holder according to claim 1 or 2, characterized in that the first and / or second removal surfaces ( 29.1 . 29.4 ) an obtuse angle (ε ₁ , ε ₂ ), in particular in the range between 100 ° and 140 °, include, particularly preferably the first Abtragflächen ( 29.1 ) are set in the range between 100 ° and 120 ° to each other, and / or that the second removal surfaces ( 29.4 ) are employed in the range between 120 ° and 140 ° to each other. Chisel holder according to one of claims 1 to 3, characterized in that the removal surfaces ( 29.1 . 29.4 ) in the region of the plug approach side at least in some areas via a transition section ( 29.2 . 29.5 ) are interconnected. Chisel holder according to one of claims 1 to 4, characterized in that the insertion projection ( 30 ) at least partially in the region of the ablation surfaces ( 29.1 . 29.4 ) is connected to the plug-in side. Chisel holder according to one of claims 1 to 5, characterized in that the longitudinal axis of the plug-in extension ( 30 ) and the median longitudinal axis (MLL) of the first or second ablation surfaces ( 29.1 . 29.4 ) include an angle (β, μ) in the range between 100 ° and 130 °. Chisel holder according to one of claims 2 to 6, characterized in that the two first removal surfaces ( 29.1 ) in the feed direction (v) at least partially in front of the insertion projection ( 30 ) and the two second removal surfaces ( 29.4 ) in the feed direction (v) at least in some areas behind the insertion projection ( 30 ) are arranged. Chisel holder according to one of claims 1 to 7, characterized in that the first removal surfaces ( 29.1 ) at least partially the underside of a front apron ( 22 ) form. Chisel holder according to one of claims 1 to 8, characterized in that the second removal surfaces ( 29.4 ) at least partially form the underside of a rear support lug. Chisel holder according to one of claims 1 to 9, characterized in that the central longitudinal axis ( 24.1 ) of the bit holder ( 27 ) at least partially between the first and / or second removal surfaces ( 29.1 . 29.4 ) is arranged. Chisel holder according to one of claims 1 to 10, characterized in that the angle (α) between the central longitudinal axis (MLL) of the prism of the first Abtragflächen ( 29.1 ,) and the central longitudinal axis ( 24.1 ) of the bit holder ( 27 ) in the range between 40 ° and 60 °, more preferably between 45 ° and 55 °. Chisel holder according to one of claims 1 to 11, characterized in that the angle (φ) between the central longitudinal axis of the prism of the second Abtragflächen ( 29.4 ) and the central longitudinal axis ( 24.1 ) of the bit holder ( 27 ) in the range between 70 ° and 90 °, more preferably between 75 ° and 85 °. Chisel holder according to one of claims 1 to 12, characterized in that the chisel holder ( 27 ) in a flushing channel ( 28 ) and that the flushing channel ( 28 ) at least in regions in the region between the second removal surfaces ( 29.4 ) exit. Chisel holder according to one of claims 1 to 13, characterized in that the first and the second removal surfaces ( 29.1 . 29.4 ) each form a Abtragflächenpaar in which the Abtragflächen ( 29.1 to 29.1 and 29.4 to 29.4 ) are each made in a V-shape to each other. Chisel holder according to claim 14, characterized in that in each case a first removal surface ( 29.1 ) of the first Abtragflächenpaars and a second Abtragfläche ( 29.4 ) of the second Abtragflächenpaars each other at an angle (ω), preferably in the range between 120 ° and 160 °, are employed, and form a support region. Chisel holder according to one of claims 14 or 15, characterized in that the central longitudinal axis of the plug-in extension ( 30 ) is in the angular range of -10 ° to + 10 ° to the bisector of the first and second Abtragflächenpaars. Chisel holder according to one of claims 1 to 16, characterized in that the surface normals of the first and / or second removal surfaces ( 29.1 . 29.4 ) inclined to the feed direction (v) run. Chisel holder according to one of claims 1 to 17, characterized in that between the first and / or the second Abtragflächen ( 29.1 . 29.4 ) a bisecting the receiving plane is arranged, and that the longitudinal axis of the plug-in approach ( 30 ) is arranged symmetrically to this plane. Chisel holder according to one of claims 1 to 18, characterized in that the connection region of the plug-in extension ( 30 ) to the support body ( 21 ) at least 80% in the area of the first ablation surfaces ( 29.1 ) Abtragflächenpaars formed is arranged.

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