EP3122998A1

EP3122998A1 - Pick, in particular a round shaft pick

Info

Publication number: EP3122998A1
Application number: EP15709929.2A
Authority: EP
Inventors: Karl Kammerer; Heiko Friederichs
Original assignee: Betek GmbH and Co KG
Current assignee: Betek GmbH and Co KG
Priority date: 2014-03-24
Filing date: 2015-03-13
Publication date: 2017-02-01
Anticipated expiration: 2035-03-13
Also published as: DE102014104040A1; US10260341B2; CN106460508A; US20170030191A1; EP3492696A1; US20190195069A1; CN106460508B; ES2747709T3; PL3122998T3; US10662770B2; DK3122998T3; EP3122998B1; WO2015144450A1

Abstract

The invention relates to a pick, in particular a round shaft pick, having a pick head and a pick shaft, having a support element which has a centring lug on the underside thereof, wherein the centring lug has a centring surface which extends inclined with respect to the central longitudinal axis of the pick and merges into a seat surface. To this end circumferential channel according to the invention is disposed in the transition region from the centring surface to the seat surface and the depth of the channel relative to the seat surface is greater than or equal to 0.3 mm. The pick has an optimised rotatability and thus a low wear.

Description

Chisel, in particular round shank chisel

The invention relates to a chisel, in particular round shank chisel, with a chisel head and a chisel shank, with a support member having on its underside a projecting spigot and wherein the spigot has an inclined to the central longitudinal axis of the chisel centering surface, which merges into a seat surface.

Such a bit is known from DE 37 01 905 C1. In this case, the fastening sleeve is designed as a clamping sleeve, which is formed from a resilient material, such as steel. It has a longitudinal slot which is bounded by sleeve edges. By means of the longitudinal slot, the fastening sleeve be varied diameter, wherein the sleeve edges to move toward each other (small diameter) or spaced from each other (large diameter sleeve). In this way, different clamping states can be achieved. On the mounting sleeve designed as a wear protection disk support member is mounted. This support member has a circular cross-section and is penetrated by a bore. In this case, the bore is dimensioned such that the fastening sleeve is held in a bias state with reduced outer diameter relative to its relaxed state. The outer diameter thus produced is chosen such that the clamping sleeve can be inserted with little or no force into a bit holder of a chisel holder. The insertion movement is limited by means of the support element. Upon further insertion of the drill collar in the bore, the support member is moved in a non-covered by the clamping sleeve portion of the drill collar. Then, the fastening sleeve jumps radially and clamps in the bore of the bit holder. In this way, the round shank bit is axially captive, but freely rotatably supported in the circumferential direction. To disassemble the chisel, it is driven out of the chisel holder by means of a dome which acts on the back of the chisel shaft. EP 1 427 913 B1 discloses a disc for a rotary cutting bit comprising: a front side and a back side, the front side having a plurality of ribs and the rear side having a plurality of recesses. The rear side furthermore has a bevelled edge arranged circumferentially to a central bore. The recesses are uniformly spaced from each other and to the chamfered edge. The bevelled edge angles sharply into the surface of the back. The sharp angle can cause the disc does not rest flat on the holding block below, resulting in increased abrasion of the disc and the holding block. Furthermore, the sharp transition can cause the Disk jammed and their rotation is prevented, resulting in a one-sided wear of the cutting bit.

In EP 2 639 402 A2 a chisel, in particular round shank chisel, with a chisel head and a chisel shank is therefore proposed, wherein a fastening sleeve is held in the region of the chisel shank and with a support element having a guide region, wherein the support element has a protruding surface on its underside Has centering approach. The centering lug has a centering surface which extends inclined to the central longitudinal axis of the chisel and which, via a recessed recess, merges into a circumferential support surface running radially to the central longitudinal axis. The recess is incorporated in the centering surface and the support surface so that it receives an opposite sharp edge of the chisel holder in the mounted state. The support element is therefore not within the scope of manufacturing tolerances on the edge of the chisel holder, whereby a flat support of the support element is ensured on the provided support surface of the chisel holder. As a result, the abrasion of the support member and the bit holder is reduced while improving the free rotation of the disc. In the transition from the centering surface to the recess, however, results in an edge. This represents a continuity jump with a negative effect on the rotation- and thus wear behavior. Furthermore, through the recess molded into both the support surface and the centering surface, removal material can reach the area of the drill shank and hinder the rotation of the bit there and the wear increase. A further disadvantage arises from the fact that the contact surface between the centering surface of the support element and the corresponding surface of the centering receptacle of the bit holder is reduced by the recess, whereby the surface pressure increases on the remaining surface under the same load. This also leads to increased wear in this area while reducing the lateral guidance of the support element. It is therefore an object of the invention to provide a chisel of the type mentioned with optimized wear behavior. The object of the invention is achieved in that a circumferential groove is arranged in the transition region from the centering surface to the seat surface and that the depth of the groove relative to the seat surface is greater than or equal to 0.3 mm.

In assembly position, the support element lies with its seat surface on a wear surface of a chisel holder. When new, the groove releases the associated edge region of the chisel holder, which leads to a flat support of the support element and a free rotation. Due to the load during use wear the support member and the bit holder in the region of the seat or the wear surface. This creates on the bit holder in the groove a circumferential bead. This results from the fact that the support element abrades the wear surface of the bit holder due to the rotation of the bit and the support element. With the bead, the support element receives an additional lateral guidance, whereby, for example, jamming of the support element and thus a one-sided and thus rapid wear of the support element and the chisel can be safely avoided. Through the groove and the cut into the groove portion of the bit holder forms a labyrinth-like sealing area, which reduces the penetration of waste material in the region of the drill collar. Thus, the wear is reduced in this area and the free rotation of the chisel improved. The depth of the groove of at least 0.3 mm ensures a safe lateral guidance and a noticeable reduction of the entry of space material. The bit holder should be harder than the support element in the area of the wear surface. This allows the bit holder to survive multiple wear cycles of the bit. If a chisel is worn, a new chisel can be combined with the chisel holder. The groove of this new bit then picks up the bead, maintaining the ideal support of the support element on the wear surface of the bit holder.

According to a preferred embodiment variant of the invention, it can be provided that the centering surface merges tangentially into the surface of the groove. The centering surface thus merges seamlessly into the surface formed by the groove. As a result, no continuity jump forms, which has a positive effect on the rotational behavior and thus the wear of the bit and the support element. Due to the continuous transition from the centering surface into the surface of the groove, the surface for receiving laterally acting forces is increased, which leads to a lower surface pressure and thus to a reduced wear in the region of the centering of the chisel holder.

A good lateral guidance of the support element results from the fact that the groove has a depth between 0.3 mm and 2 mm, preferably between 0.5 mm and 1, 5 mm, relative to the seat surface. If the depth of the groove chosen smaller than 0.3 mm, so there is no sufficiently pronounced bead, which leads to a lateral stabilization of the support element. Groove depths up to 2 mm provide a good sealing effect (labyrinth seal) between the bead and the groove. If the dimensional range between 0.5 mm and 1.5 mm is selected, the result is a good combined effect between the seal and the side guide.

The groove is, starting from the seat, incorporated in the support element. As a result, the material thickness of the support element in the region of the groove around its fe reduced. In order nevertheless to obtain sufficient stability and durability of the support element, it may be provided that the ratio of the thickness of the groove receiving part of the support element to the depth of the groove is at least 2 to 1 and / or that the material thickness between the groove and one of the seat opposite support surface is at least 2 mm.

A uniform abrasion of the chisel holder over the entire wear surface without the formation of a free rotation disabled edge on the outer circumference of the wear surface can be achieved in that the support member has a diameter between 38 mm and 49 mm, preferably between 40 mm and 48 mm , Thus, the support member includes at its outer periphery at least approximately with the wear surface of the chisel holder.

The range between 38 mm and 49 mm is to be preferred in particular for use in road milling. In this case, a diameter of 38 mm forms a lower limit, which ensures sufficient carrying capacity of the support element. 49 mm represents an upper limit, where the friction between bit holder, support element and chisel is such that an optimized turning behavior of the bit is possible. An optimized rotational behavior is when free rotation of the bit is possible in order to avoid one-sided wear of the bit, but at the same time excessive rotation of the bit are avoided, resulting in increased abrasion of a bearing surface of the bit, the support element and the wear surface of the chisel holder leads. A diameter range between 40 mm and 48 mm is preferred for large milling provide, and this area also forms an optimum between sufficient bearing capacity of the support element and turning capability of the bit. A particularly preferred variant of the invention is such that the groove has a rounded, in particular circular contour and that the radius of the contour in a range between 0.5 mm and 6 mm, particularly preferably at a radius of 1, 5 mm. Furthermore, it can be provided that the surface of the groove is transferred over a rounding section in the surface of the seat. By the circular contour or the rounded transition from the surface of the groove in the surface of the seat edges in the area between the seat and the wear surface are avoided. This leads to an improved rotatability of the support element and thus to a reduced wear of the bit. From a lower radius of the groove of 0.5 mm ensures that the bead is not formed too sharp-edged to achieve good rotation of the support element. In this case, sufficient stability of the support element is achieved up to a radius of 6 mm. The rotation can be improved in particular by the fact that the rounding section is formed by a circular arc section with a second radius in a range between 0.2 mm and 25 mm, particularly preferably of 1, 0 mm.

Also in the region of the transition from the groove to the seat surface, it is advantageous with regard to the rotatability of the support element and of the bit when there are no sharp edges. Therefore, it can be provided that the rounding section merges tangentially into the seat surface.

A secure guidance of the support element on the drill collar can be achieved in that the support element forms a guide region, which is formed by a bore extending in the direction of the central longitudinal axis of the bit, that the guide region is transferred into the centering surface via a peripheral web and that the web has a width in a range between 0.1 mm and 2.0 mm, more preferably 0.5 mm. The guide area is in the assembled state opposite a cylindrically shaped centering of the drill collar. In this case, the diameter of the centering section is selected such that it can move with a predetermined play in the bore forming the guide area. The rotary bearing thus formed ensures a free rotation between the guide region of the support element and the centering of the drill collar with low lateral offset transverse to the central longitudinal axis of the bit. Since both the guide region and the centering section are formed as continuous cylindrical surfaces with constant diameters, the free rotation of disabled edges and transitions can be avoided. The guide extends over the entire length of the guide region and the centering, resulting in a high mechanical strength in this area. By the web is avoided that the material thickness of the centering approach in the transition to the guide area is too small and thus sensitive to mechanical damage. At the same time, the width of the web is to be chosen as small as possible in order to obtain the largest possible centering surfaces and guide areas under the given spatial conditions and the preferred inclination of the centering surface. The invention will be explained in more detail below with reference to an embodiment shown in the drawings. Show it:

1 is a side view of a chisel in its mounting position on a chisel holder,

FIG. 2 shows a detail marked II in FIG. 1, 3 shows a perspective view of a support element shown in FIGS. 1 to 2, FIG.

Figure 4 in a sectional side view a detail of a in the figures

1 to 3 shown supporting element.

Figure 1 shows a side view of a chisel 10 in its mounting position on a chisel holder 40, wherein a portion of the chisel holder 40 is shown in a sectional view. The bit 10 is designed as a round shank chisel. It has a chisel head 13, which merges into a chisel tip 14, consisting of hard material, for example hard metal. For this purpose, a cup is incorporated in the chisel head 13 at the end, in which the chisel tip 14 is soldered. On the side opposite the chisel tip 14, the chisel head 13 merges into a cylindrical centering section 12, which merges into a cylindrical chisel 11 after a rejuvenation region 12. The chisel head can pass directly into the chisel shaft 11 even without the rejuvenation area. The chisel shank 11 is in the representation predominantly covered by a holding projection 43 of the chisel holder 40 and by a fastening sleeve 20. In the drill collar 11, a circumferential groove 15 is introduced. The bit 10 is formed with its chisel shank 11, its chisel head 13 and its chisel tip 14 rotationally symmetrical to the running through the chisel tip 14 center longitudinal axis. In the area of the chisel shank 1, the fastening sleeve 20 is arranged. It is made of a sheet material, such as steel. In this case, retaining elements 21 are formed from the sheet material and pressed into the area enclosed by the fastening sleeve 20. The holding elements 21 are thereby cut free along two edges which extend in the circumferential direction of the fastening sleeve 20. The fastening sleeve 20 is rolled in such a way that a circular cross-section results, leaving a clamping slot 23. The holding elements 21 engage in the groove 15 of the chisel Shaft 11 on. The fastening sleeve holds the chisel 10 with the holding elements 21, while it is itself held by its bias in the holding projection 43 of the chisel holder 40. It thus enables a rotation of the bit 10 about its central longitudinal axis, while a movement in the direction of the central longitudinal axis is blocked.

Between the chisel head 13 and the holding lug 43 of the chisel holder 40, a support member 30 is provided.

The bit holder 40 has a base part 41, to which a lower side projecting tab 42 is formed. The base member 41 also carries the integrally formed retaining lug 43, in which a bit holder 46 is introduced as a cylindrical bore. In this case, the bit receptacle 46 is designed as a through hole, which is open at its two longitudinal ends. By the plug neck 42 facing the end of the bit holder 46, a Austreibdorn (not shown) of a Austreibwerkzeuges be introduced. This Austreibdorn then acts on the free end of the drill collar 11 a. The plug projection 42 remote from the end of the bit holder 46 opens into a cylindrical portion 44 of the retaining projection 43. On the outer periphery of the retaining projection 43 wear marks 45 are provided in the form of circumferential rings.

FIG. 2 shows a detail labeled II in FIG. 1. The chisel head 13 is closed in the direction chisel shaft 11 with a collar 13.2, which forms a support surface 13.1. This rests on a support surface 31.1 of the support element 30, which is formed by a recess 31 on the upper side of the support element 30. The support surface 31.1 is correspondingly limited on the outside by an edge 31.2. On the opposite side of the support surface 31.1, the support member 30 has a seat surface 33, with which it rests on a wear surface 47 of the cylindrical portion 44 of the holding lug 43. The support element 30 is essentially chen rotationally symmetrical to the central longitudinal axis of the chisel 10 constructed. The seat 33 passes over an inner circumferential groove 35 in an inclined to the central longitudinal axis extending centering surface 34.1 of a spigot 34 over. As clearly illustrated in FIG. 2, the centering lug 34 of the support element 30 is inserted into a correspondingly shaped centering receptacle 48 of the chisel holder 40.

Along the central longitudinal axis, the support member 30 has a bore, through which a guide portion 36 is formed for guiding the chisel 10. In the assembly position, the centering section 12 of the drill collar 11 is assigned to the guide region 36. In this way arises between the guide portion 36 and the centering 12 a pivot bearing. It is important to ensure that the outer diameter of the cylindrical centering 12 is matched to the inner diameter of the guide portion 36 that a free rotation between the support member 30 and the centering 12 is maintained. The play between these two components should be chosen so that the smallest possible lateral offset (transverse to the central longitudinal axis of the bit (10)) is formed. In the exemplary embodiment, the diameters of the guide region 36 and of the centering section remain the same over their entire axial length. As a result, the angles of rotation of the bit 10 which obstruct the edges and discontinuities are also avoided in this area. As already shown in FIG. 1, after a tapering region 12.1, the centering section 12 merges into a cylindrical tool shank 11.

The chisel shaft 11 is held on the mounting sleeve 20 in the retaining lug 43 of the chisel holder 40. At its upper end, the fastening sleeve 20 has a chamfer 22. During operation, the bit 10 may rotate about the central longitudinal axis. The free rotation ensures that I wear the chisel 10 evenly over its entire circumference. In this case, the loosely placed and held by the centering portion 12 of the drill collar 1 support member 30 rotates, whereby the rotation of the chisel 10 is further improved overall. By the rotation and the high mechanical load of the bit 10 also a wear of the bit holder 40, mainly in the upper portion 44 of the holding lug 43 is carried out by the load, the wear surface 47 is abraded. The present wear of the holding projection 43 can be evaluated via the wear marks 45 shown in FIG.

Due to the relative movement between the support member 30 and the retaining lug 43, the wear surface 47 of the retaining lug 43, which is flat when new, works into the groove 35 of the support element 30, as shown in FIG. By thus forming according to the Kontor the groove 35 bead 47.1, the support member 30 receives an additional lateral guidance, which has a positive effect on the rotation of the support member 30 and thus of the bit 10. The centering surface 34.1 merges tangentially into the surface of the groove 35, so that no edges obstructing the rotatability are formed. Accordingly, the surface of the groove 35 via a rounding section without sharp edges in the seat 33 via. The groove 35 counteracts with its radially outer surface portion forces acting radially inwardly on the support member 30. Radially outward forces counteract the radially inner surface portion. This reduces the force which must be absorbed by the centering surface 34.1, which leads in this area to a reduced surface pressure and correspondingly to a reduced wear. In addition, this support also counteracts a wobbling movement in the disc plane of the support element 30, which causes a significant reduction in wear on the bit holder 40. Farther serves the groove with her worked from the wear surface 47 counterpart as a labyrinthine seal. Abraummaterial, which passes between the seat 33 and the wear surface 47 is prevented by this seal on further penetration and so does not or only to a reduced extent in the area of the drill collar 11th

In the figures 3 and 4, the support member 30 is shown again. As these illustrations illustrate, the seat surface 33 merges into the groove 35 arranged circumferentially to form a central bore. The groove 35 follows the likewise circumferentially arranged to the central bore centering projection 34 with the inclined centering 34.1. The surface of the central bore forms the guide region 36. The centering projection 34 is closed by a circumferential web 39.

In the formed edge 31.2 on the top of the support member 30 are formed as radially extending grooves recesses 32 are provided. The representation of Figure 3 can also be seen that the support member 30 is formed to the recesses 32 rotationally symmetrical to its central longitudinal axis.

FIG. 4 shows in a lateral sectional view a section of a support element shown in FIGS. 1 to 3. It has on its upper side the cup-shaped recess 31, which is bounded on the outside by the rounded edge 31.2. The recess 31 forms the support surface 31.1, which merges into the guide region 36 via a rounding. Turned away from the recess 31, the support member 30, the seat 33, which is arranged plane parallel to the support surface 31.1. The seat surface 33 merges with the centering shoulder 34 via the groove 35. The subsequent to the groove 35 centering 34.1 of the spigot 34 is arranged inclined to the guide portion 36 shown by a central bore. Of the Centering lug 31 is closed by the web 39, which connects the centering surface 34.1 and the guide portion 36.

In the embodiment shown, the depth of the groove 35 relative to the seat surface 34 is one millimeter at a marked by an arrow radius 37 of 1, 5 mm. The thickness of the support element 30 is between the support surface 31.1 and the seat 33 five millimeters. This ensures a sufficient material thickness between the groove 35 and the support surface 31.1. A second radius 38 of the rounding section between the groove 35 and the seat surface 33 is one millimeter, wherein the rounding section merges tangentially into the surface of the groove 35 and the seat surface 33. The width of the web is in the embodiment 0.5 mm.

Claims

claims

Chisel (10), in particular round shank chisel, with a chisel head (13) and a chisel shank (11), with a support element (30) having on its underside a projecting centering shoulder (34) and wherein the centering lug (34) extends to the center longitudinal axis of the Chisel (10) has inclined centering surface (34.1), which merges into a seat surface (33),

characterized,

a peripheral groove (35) is arranged in the transition region from the centering surface (34.1) to the seat surface (33) and that the depth of the groove (35) is greater than or equal to 0.3 mm with respect to the seat surface (33).

Chisel (10) according to claim 1,

characterized,

the centering surface (34.1) merges tangentially into the surface of the groove (35).

Chisel (10) according to claim 1 or 2,

characterized,

the groove (35) has a depth of between 0.3 mm and 2 mm, preferably between 0.5 mm and 1.5 mm, with respect to the seat surface (33).

4. chisel (10) according to one of claims 1 to 3,

characterized,

in that the ratio of the thickness of the groove-receiving part of the support element (30) to the depth of the groove (35) is at least 2 to 1 and / or that the material thickness between the groove (35) and a support surface (31.1 ) is at least 2 mm.

5. chisel (10) according to any one of claims 1 to 4,

characterized,

in that the support element (30) has a diameter between 38 mm and 95 mm.

6. chisel (10) according to one of claims 1 to 5,

characterized,

in that the groove (35) has a rounded, in particular circular contour, and that the radius (37) of the contour lies in a range between 0.5 mm and 6 mm, particularly preferably at a radius (37) of 1.5 mm.

7. bit (10) according to any one of claims 1 to 6,

characterized,

in that the surface of the groove (35) is transferred over a rounding section or a chamfer into the surface of the seat surface (33).

8. chisel (10) according to claim 7,

characterized,

in that the rounding section is formed by a circular arc section having a second radius (38) in a range between 0.2 mm and 25 mm, particularly preferably 1, 0 mm. Chisel (10) according to claim 7 or 8,

characterized,

that the rounding section merges tangentially into the seat surface (33).

A bit (10) according to any one of claims 1 to 9,

characterized,

in that the support element (30) forms a guide region (36), which is formed by a bore extending in the direction of the central longitudinal axis of the bit (10), in that the guide region (36) is guided into the centering surface (34.1) via a circumferential web (39). is transferred and that the web (39) has a width in a range between 0.1 mm and 2.0 mm, more preferably of 0.5 mm.