US20160003041A1

US20160003041A1 - Variable Angle Cutting Bit Retaining Assembly

Info

Publication number: US20160003041A1
Application number: US14/790,618
Authority: US
Inventors: Joseph Fader; Alfred Lammer
Original assignee: Sandvik Intellectual Property AB
Current assignee: Sandvik Intellectual Property AB
Priority date: 2014-07-03
Filing date: 2015-07-02
Publication date: 2016-01-07
Also published as: CN105240010A; AU2015203149A1; EP2963237A1

Abstract

A cutting bit retaining assembly for mounting a cutting bit at a cutting machine. The assembly includes a holder body to receive a shank like adaptor with a cutting bit demountable at one end of the adaptor. An annular shoulder is provided at the cutting bit mounting end of the adaptor having a wedge configuration, so as to mount the cutting bit at a tilted angle relative to the shank of the adaptor to provide a desired cutting bit attack angle.

Description

RELATED APPLICATION DATA

This application claims priority under 35 U.S.C. §119 to EP Patent Application No. 14175520.7, filed on Jul. 3, 2014, which the entirety thereof is incorporated herein by reference.

FIELD OF INVENTION

The present disclosure relates to a cutting bit retaining assembly for mounting a cutting bit at a cutting machine and in particular although not exclusively, to the assembly configurable to change the attack angle of the bit.

BACKGROUND

Rock cutting and excavation machines have been developed for various specific applications including mining, trenching, tunnelling, foundation drilling, road milling, etc. Typically, a drive body in the form of a rotatable drum or drill head includes a plurality of replaceable cutting bits that provide the points of contact for the material or mineral face.
For example, a mobile mining machine comprises a rotatable cutting head with the cutting bits provided on rotating drums. As the bits contact the surface of the rock they occasionally break and inevitably wear resulting in decreased cutting inefficiency and a need for replacement. It is therefore desirable to mount the cutting bits at the cutting head (or drive body) via releasable mounting assemblies that enable the bits to be replaced conveniently and quickly during servicing and repair.
Cutting bit (alternatively termed ‘cutting pick’ or ‘tool pick’) mountings are described in U.S. Pat. No. 3,342,531; U.S. Pat. No. 3,627,381; U.S. Pat. No. 3,932,952; U.S. Pat. No. 4,343,516; U.S. Pat. No. 5,261,499; WO 96/31682; U.S. Pat. No. 5,799,741; WO 98/39553; US 2008/0258536; US 2008/0309148; WO 2010/027315; US 2011/0278908; EP 1069278; EP 1033216; DE 102009052351 and EP 2514918.
Cutting bits have been developed that may be considered to fall in at least two general categories. A first general type comprises a nose portion attached at one end of an elongate shaft whilst a second type comprises a bit having an inner cavity that fits onto an end of an ‘adaptor’ that comprises a projection head and an elongate shaft, with the head received within the inner cavity of the bit and the shank secured at a through bore extending within a mount body.
The angle by which the bit strikes the rock is referred to as the ‘attack angle’ and is an important cutting parameter. Super hard pick materials, such as diamond composites, exhibit enhanced wear resistance and are ideal for certain rock types. However due to their brittleness, a larger attack angle of 55 to 60° is preferred in contrast to a more conventional range being 40 to 50°. Conventional pick holders or mounts fix the pick at a predetermined attack angle and it is currently not possible for an operator to conveniently change the attack angle to take advantage of the different pick materials that are available to best suit particular cutting applications and rock or mineral types.

SUMMARY

The present disclosure provides a cutting bit retaining assembly to allow the setting of different pick mounting angles. Moreover, the cutting bit retaining assembly allows the convenient and rapid interchange of picks formed from different materials that accordingly are optimised via the employment of different attack angle settings relative to a pick holder. The cutting bit retaining assembly further allows for the convenient interchange (within the working environment) and reliable mounting of different picks at a cutting head without having to exchange the head mounted pick holder.
The above is achieved via a pick retaining assembly in which a pick is releasably mounted at an adaptor, having a shaft-like configuration that, is in turn, releasably mounted at a pick holder. In particular, the adaptor is configured with a pick mounting projection at one end of a shaft that is orientated at a predetermined transverse angle relative to a longitudinal axis of the shaft. Such an arrangement is effective to mount the pick at a tilted orientation representing a predetermined attack angle. By interchange of different adaptors having respective mounting projections set at different transverse angles relative to the central axis of the shaft, the pick attack angle may be adjusted conveniently. In particular, the adaptor may be releasably retained at the holder via a conventional retainer optionally in the form of a releasably clip, ring or bolt engageable with the shaft and pick holder. Additionally, the pick may be releasably engaged at the male projection by a corresponding retainer to provide a releasable couple between the projection and the bit.
According to a first aspect, there is provided a cutting bit retaining assembly for mounting a cutting bit at a cutting machine, the assembly including a holder body having a bore extending in a direction between a forward and a rearward end of the body, an end surface positioned at an entrance of the bore; an elongate bit shaft having a central longitudinal axis and configured to extend axially into the bore to mount the shaft at the holder body; the shaft terminated at one end by a male projection configured to be received within a female cavity formed within a cutting bit attachable to the shaft the projection configured to releasably retain the bit at the shaft via a retainer; a shoulder projecting radially outward from the shaft at an axial junction of the male projection and a first end of the shaft, an underside surface of the shoulder configured to mate in touching or near touching contact with the end surface to support mounting of the shaft at the holder body; and a central longitudinal axis of the male projection is aligned transverse to the longitudinal axis of the shaft such that the male projection is fixed at a generally tilted angle θ relative to the shaft, so as to mount the bit at a predetermined attack angle relative to the holder body.
Advantageously, the bit is rotatably mounted at the projection whilst the adaptor (comprising the elongate shaft and male projection) is non-rotatably mounted at the holder body so as to maintain the predetermined attack angle of the bit when mounted at the adaptor.
In a further aspect, a set or kit of parts including a plurality of adaptors having respective shoulders of different configurations, so as to provide respective male projections that are inclined or tilted relative to the longitudinal axis of the shaft at different respective angles, is provided. Such an arrangement allows a user to conveniently interchange different adaptors at the holder body to obtain the desired bit attack angle in use.
The shoulder is configured as a wedge having an axially thicker part relative to an axially thinner part, the underside surface provided at an underside of the wedge. The respective parts represent circumferential regions of the shoulder around the central axis. The relative axial thickness of the shoulder in a circumferential direction around the axis changes according to a smooth seamless transition so as to provide an uninterrupted annular surface for supporting contact with the rearward surface of the bit and the axially forward surface of the holder body. Such an arrangement is advantageous to effectively distribute the loading forces transmitted through the shoulder from the bit to the holder body. Accordingly, the shoulder includes a forward facing surface to mate with a rearward facing surface of the bit.
The angle by which the longitudinal axis of the male projection is transverse to the longitudinal axis of the shaft is in a range of 1 to 60°; 1 to 40°; 1 to 30°; 2 to 20°; and 5 to 15°. Such an arrangement is effective to provide the desired range of different attack angle settings available by interchanging different adaptors at the holder body, with each adaptor having a different respective tilt angle.
The shaft or the shoulder further includes a first locking member and the holder body has a second locking member, the first and second members being configured to engage and prevent the shaft from rotating within the bore. Optionally, the first member has a male abutment projecting radially from the shaft or axially from the shoulder and the second member has a recess to at least partially receive the first member. Interlocking lug and groove arrangements are a convenient means of rotatably locking the adaptor at the holder body to prevent undesirable rotation.
According to further embodiments, the adaptor and holder body may have a plurality of lug and recess mating components distributed and spaced apart circumferentially around the central axis of the shaft. Additionally, respective locking components may be provided at different axial positions of the adaptor and holder body including for example axially forward, axially mid and axially rearward positions relative to the forward mounted bit.
The shoulder can be formed integrally with the shaft. Such an arrangement provides a reliable and strong adaptor, effective to reliably transmit the loading forces from the bit to the holder body and to reduce the creation of stress concentrations.
An axially rearward region of the male projection can include a concave or tapered annular surface extending axially forward from the shoulder to mate in close touching contact with a convex or tapered surface within the cavity of the bit. Accordingly, the loading forces are transmitted evenly and effectively from the bit to the adaptor whilst allowing the bit to rotate on the adaptor.
The shaft has a length sufficient to extend axially through the bore, such that a rearward second end of the shaft projects from the rearward end of holder body; and the assembly further includes a retainer mountable at or towards the second end of the shaft to releasably retain the shaft at the holder body. The adaptor may be axially locked at the holder body via a plurality of different mechanisms including for example threaded shaft and bolt arrangements; releasable clips; hole and pin or lug and groove arrangements and locking collar or ring arrangements as will be appreciated by those skilled in the art.
Optionally, an axial length of the male projection is substantially in a range ¼ to ½ of an axial length of the shaft that extends rearwardly from the shoulder. Such an arrangement is effective to provide a secure mount of the bit at a forward end of the adaptor whilst providing a secure mount of the adaptor within the holder body.
Optionally, the retainer is a ring and the projection is an indented channel to at least partially receive the ring, such that ring is accommodated radially between the projection and the bit.
According to a second aspect, there is provided a cutting bit assembly for mounting at a cutting machine including: a retaining assembly and a cutting bit having a cutting tip at first end and a cavity projecting inwardly from a second end, the bit releasably mounted at the shaft via mating of the male projection within the cavity.
The shoulder can be annular to provide an annular underside surface. The shoulder has an axial length sufficient to axially separate and provide a spatial gap between the second end of the bit and the forward end of the holder body. The spatial gap is sufficient to provide non-touching contact between the bit and the holder body to ensure loading forces are transmitted from the bit to the holder body exclusively via the adaptor. The minimum axial length of the shoulder is therefore configured to avoid touching contact between the bit and the holder body over the entire tilt-angle range of the male projection. The axial separation distance between the rearwardmost part of the bit and a respective forwardmost part of the holder body may vary for different adaptors having different projection tilt angles.
The foregoing summary, as well as the following detailed description of the embodiments, will be better understood when read in conjunction with the appended drawings. It should be understood that the embodiments depicted are not limited to the precise arrangements and instrumentalities shown.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is an external side view of a cutting bit according to the present disclosure.

FIG. 2 is cross-sectional side view of the cutting bit assembly of FIG. 1.

FIG. 3 is an exploded external perspective view of the cutting bit assembly of FIG. 2 with the cutting bit removed for illustrative purposes.

FIG. 4 is an exploded external perspective view of a cutting bit retaining assembly according to a further embodiment of the present disclosure with the cutting bit removed for illustrative purposes.

DETAILED DESCRIPTION

Referring to FIG. 1, a cutting bit assembly 100 is arranged for mounting at an external surface of a rotatable cutting head (or drum) of a cutting machine (not shown). The assembly 100 includes a cutting bit 101 releasably and rotatably mounted at a cutting bit holder 103 via an elongate adaptor 102 that is, in turn, releasably mounted at bit holder body 103. Bit 101 has a generally conical shape profile having a forward end 104 that mounts a cutting tip 106 and rearward end 105 mounted at a forward end 107 of holder body 103.
Holder body 103 is mounted at the cutting head (or drum) via a mounting flange 109 projecting laterally from one side of holder body 103. A shoulder 110 projects radially outward from adaptor 102 and has a generally wedge shaped configuration. Shoulder 110 includes a forward facing annular surface 111 positioned in contact with bit rearward end 105 and a rearward facing annular surface 112 positioned in contact with an annular surface 113 at holder body forward end 107. Accordingly, shoulder 110 is configured to axially separate bit 101 from holder body 103 so that these two components are spaced apart in non-touching contact. Additionally, bit 101 via the wedge configuration of shoulder 110 is mounted at a tilted transverse angle relative to adaptor 102, so as to provide a desired attack angle when bit 101 is brought into contact with rock.
Referring to FIG. 2, adaptor 102 includes an elongate shaft 220 that extends axially rearward from shoulder 110 and in particular rearward facing surface 112. Shaft 220 is terminated at a first end by a male projection indicated generally by reference 202. Projection 202 has a substantially circular end face 210 and a main body that flares radially outward via an external concave surface 206 that terminates at its rearwardmost end via an axially short cylindrical surface 208 that extends axially forward from annular forward facing surface 111. A second end 212 of shaft 220 projects axially rearward from a rearward end 108 of holder body 103 with shaft 220 accommodated within a through bore 218 extending axially through holder body 103 between the forward and rearward ends 107, 108. An annular groove 217 is indented at shaft second end 212 to receive a retaining clip (not shown) or the like to axially lock adaptor 102 at holder body 103. Additionally, shaft 220 has an annular channel 216 positioned substantially axially mid-way between shoulder 110 and second end 212 to partially accommodate and engage with an attachment ring 215 sandwiched between shaft 220 and the internal surface that defines bore 218.
Bit 101 includes an internal cavity indicated generally by reference 201 that extends axially inward from rearward end 105. Cavity 201 is shaped and dimensioned to receive projection 202 in generally close fitting contact, such that bit 101 may be conveniently mounted and dismounted from adaptor 102 via the coupling between projection 202 and cavity 201. Additionally, bit 101 is rotatably mounted at projection 202 via an intermediate coupling ring 204 housed within cavity 201 and positioned radially between projection 202 and an internal facing surface 207 of cavity 201. In particular, an annular channel 203 is indented radially into bit 101 from cavity surface 207 to at least partially accommodate ring 204. Similarly, a corresponding channel 205 is indented within projection 202 to at least partially receive an opposite face of ring 204 such that ring 204 is accommodated within and between the respective channels 203, 205 to releasably retain bit 101 at adaptor 102.
Cavity surface 207 at the region of the cavity opening (extending axially inward from rearward end 105) has a convex curvature, so as to mate in close touching contact with the concave external surface of projection 202 at the position immediately axially forward of shoulder 110. Such a configuration optimises distribution of the loading forces imparted to bit 101 during crushing impacts to avoid stress concentrations at this region.
Shoulder 110 includes an annular configuration with forward and rearward annular surfaces 111, 112 positioned in close touching engagement contact with the respective rearward annular surface 200 at bit rearward end 105 and adaptor body annular surface 113. The respective shoulder abutment surfaces 111, 112 are aligned transverse to one another and are separated by a cylindrical surface 219. As shoulder 110 is wedge shaped it has an axial thickness that is non-uniform in a circumferential direction around longitudinal axis 211 about which shoulder 110 is centred such that surface 219 extends in the axial direction but is aligned transverse to axis 211.
In particular, a circumferential segment 214 of shoulder 110 is axially thicker than a corresponding circumferential segment 213. Accordingly, a length of cylindrical surface 219 (in the generally axial direction) is greater at the thicker segment 214 than the thinner segment 213. Additionally, and according to the specific implementation, a radial separation of cylindrical surface 219 from axis 211 at thicker segment 214 is greater than the corresponding radial separation of surface 219 from axis 211 at thinner segment 213.
This wedge configuration of shoulder 110 provides an effective angled seat for bit 101 such that the central axis 209 of bit 101 is aligned transverse to shaft axis 211 via a tilt angle θ. Axis 209 also corresponds to the central axis of projection 202 being received centrally within cavity 201. According to the specific implementation, the tilt angle by which projection 202 and bit 101 extend relative to axis 211 is in the range 8° to 12°.
To maintain the desired angular alignment of projection 202 (and hence bit 101) relative to bit holder surface 113 and shaft axis 211, adaptor 102 is rotatably locked at holder body 103 via a rotational locking mechanism. In particular, and referring to FIG. 3, the locking mechanism includes a male abutment 301 that projects radially outward from shaft 220 immediately rearward of shoulder 110 and in particular rearward facing shoulder surface 112. Accordingly, abutment 301 is formed as a lug provided at the forward end of shaft 220. A corresponding recess 300 is formed within a mouth 302 of bore 218 being shaped and dimensioned to accommodate abutment lug 301 and in turn rotationally lock adaptor 102 at holder body 103. In particular, shaft 220 is prevented from rotation about axis 211 within bore 218 via mating abutment contact between lug 301 and recess 300.
FIG. 4 illustrates an alternative embodiment in which a lug or axial projection 401 extends rearwardly from shoulder rearward facing surface 112. Lug 401 is formed as a truncated cylinder and is radially separated from shaft 220. According to the further embodiment, holder body 103 has a corresponding substantially cylindrical shaped recess 400 indented in forward facing annular surface 113 being radially separated from bore mouth 302. Accordingly, when adaptor 102 is mounted at holder body 103, lug 401 engages into recess 400 to rotationally lock shaft 220 within bore 218.
Although the present embodiment(s) has been described in relation to particular aspects thereof, many other variations and modifications and other uses will become apparent to those skilled in the art. It is preferred therefore, that the present embodiment(s) be limited not by the specific disclosure herein, but only by the appended claims.

Claims

1. A cutting bit retaining assembly for mounting a cutting bit at a cutting machine, the assembly comprising:

a holder body having a bore extending in a direction between a forward end and a rearward end of the body, an end surface being positioned at an entrance of the bore;

an elongate bit shaft having a central longitudinal axis and configured to extend axially into the bore to mount the shaft at the holder body;

the shaft terminated at one end by a male projection configured to be received within a female cavity formed within a cutting bit attachable to the shaft, the projection being configured to releasably retain the bit at the shaft via a retainer;

a shoulder projecting radially outward from the shaft at an axial junction of the male projection and a first end of the shaft, an underside surface of the shoulder being configured to mate in touching or near touching contact with the end surface to support mounting of the shaft at the holder body; and

a central longitudinal axis of the male projection aligned transverse to the longitudinal axis of the shaft such that the male projection is fixed at a generally tilted angle relative to the shaft so as to mount the bit at a predetermined attack angle relative to the holder body.

2. The assembly as claimed in claim 1, wherein the shoulder is a wedge having an axially thicker part relative to an axially thinner part, the underside surface being provided at an underside of the shoulder.

3. The assembly as claimed in claim 2, wherein the underside surface and the end surface are substantially planar to mate in close touching contact.

4. The assembly as claimed in claim 1, wherein the shoulder includes a forward facing surface to mate with a rearward facing surface of the bit.

5. The assembly as claimed in claim 1, wherein the angle that the longitudinal axis of the male projection is transverse to the longitudinal axis of the shaft is in a range 1 to 60°.

6. The assembly as claimed in claim wherein the range of the angle is 2 to 20°.

7. The assembly as claimed in claim 1 wherein the shaft or the shoulder includes a first locking member and the holder body includes a second locking member, the first and second members being configured to engage and prevent the shaft from rotating within the bore.

8. The assembly as claimed in claim 7, wherein the first member includes a male abutment projecting from the shaft or the shoulder and the second member includes a recess to at least partially receive the first member.

9. The assembly as claimed in claim 1, wherein the shoulder is formed integrally with the shaft.

10. The assembly as claimed in claim 1, wherein an axially rearward region of the male projection has a concave or tapered annular surface extending axially forward from the shoulder to mate in close touching contact with a convex or tapered surface within the cavity of the bit.

11. The assembly as claimed in claim 1, wherein the shaft has a length sufficient to extend axially through the bore such that a rearward second end of the shaft projects from the rearward end of holder body.

12. The assembly as claimed in claim 1, wherein an axial length of the male projection is substantially in a range ¼ to ½ of an axial length of the shaft that extends rearwardly from the shoulder.

13. The assembly as claimed in claim 1, wherein the retainer includes a ring and the projection includes an indented channel to at least partially receive the ring such that ring is accommodated radially between the projection and the bit.

14. A cutting bit assembly for mounting at a cutting machine comprising:

a retaining assembly including a holder body having a bore extending in a direction between a forward end and a rearward end of the body, an end surface being positioned at an entrance of the bore; an elongate bit shaft having a central longitudinal axis and configured to extend axially into the bore to mount the shaft at the holder body, the shaft terminating at one end by a male projection configured to be received within a female cavity formed within a cutting bit attachable to the shaft, the projection being configured to releasably retain the bit at the shaft via a retainer; a shoulder projecting radially outward from the shaft at an axial junction of the male projection and a first end of the shaft, an underside surface of the shoulder being configured to mate in touching or near touching contact with the end surface to support mounting of the shaft at the holder body; and a central longitudinal axis of the male projection aligned transverse to the longitudinal axis of the shaft such that the male projection is fixed at a generally tilted angle relative to the shaft so as to mount the bit at a predetermined attack angle relative to the holder body; and

a cutting bit having a cutting tip at first end and a cavity projecting inwardly from a second end, the bit being releasably mounted at the shaft via mating of the male projection within the cavity.

15. The assembly as claimed in claim 14, wherein the shoulder is annular to provide an annular underside surface.

16. The assembly as claimed in claim 11, further comprising a retainer mountable at or towards the second end of the shaft to releasably retain the shaft at the holder body.