AU2010246885B2 - Cutting device for a mining machine - Google Patents

Abstract

The invention relates to a cutting device for a mining machine, in particular a shearer. Said machine comprises a tool carrier, in particular a shearer drum that is rotatably mounted about a rotational axis and at least one cutting tool (1) that is fixed to the tool carrier. The cutting tool (1) comprises a tool base body (3) and a cutting insert (1) that consists of a diamond composite material, or a harder material, and is fixed in a receiving bore (6) of said body. The cutting tool is oriented on the tool carrier at an incident cutting angle (ß) of 45 - 58°, preferably 47 - 54° and especially preferably 49°. The tip (2) of the cutting insert (1) is substantially conical and the nose angle (α) is 60 - 75°.

Description

Cutting device for a mining machine The invention relates to a cutting device for a mining machine, in particular a shearer, including a tool carrier, in particular a shearer drum, that is rotatably mounted about a rotational axis and at least one cutting tool that is fixed to the tool carrier and comprises a tool base body and a cutting insert made of a diamond composite material or a harder material and fixed in a receiving bore of the tool base body. Cutting tools for mining machines are, for instance, known in the form of so-called chisels, which are, for instance, used in coal mining or in tunnelling. Chisels are usually disposed about the periphery of a cutting or shearing drum, wherein, by selecting the appropriate incident cutting angle, it will be achieved that the usually tapering chisels, due to the rotating movement of the cutting or shearing drum, will engage with the material to be extracted, or the rock to be removed, in such a manner that material, or rock, will be detached from the surface of the mine face by cutting or scraping. Chisels, as a rule, are each comprised of a base body and a cutting insert fixed in a receiving bore of the base body. In order to also enable the efficient removal of harder rock, the cutting insert is made of a particularly hard and wear-resistant material. In this respect, tungsten carbide or a tungsten-carbide-cobalt composite has, for instance, been proposed as a material for the cutting insert. A particularly wear-resistant configuration will be achieved by using cutting tools or chisels including tips of diamonds or polycrystalline diamond composites. The cutting insert of the cutting tool in such cases may just be provided with an outer coating of a diamond composite material or be completely comprised of such a diamond composite material.

2 US-5,161,627, for instance, shows and describes a round-shaft chisel including a cutting insert that is designed to be conical with a rounded-off tip. A layer of a polycrystalline diamond composite is applied on the surface of the cutting insert. The layer is about 0.04 inch (0.1 cm). A conical cutting insert coated with a polycrystalline diamond material can also be taken from US-4,811,801. In respect to the subject matter of US 6,733,087, diamond, a polycrystalline diamond material, a cubic boronitride binder, free carbide or combinations thereof are cited as materials to be used for a wear-resistant coating of a cutting insert. Based on a new generation of diamond composite materials, which are described in W088/07409 Al and W090/01986 Al, a cutting tool including a tapering cutting insert made of diamond crystals that are interconnected by a silicon carbide matrix has been proposed in EP-1283936 Bl. To connect the cutting insert with the tool base body, a metal matrix composite is indicated. A diamond composite material has a higher hardness than any substance naturally occurring on earth and, therefore, is ideal for an application as a cutting insert. It is, however, also a very expensive material. In recent times, materials harder than diamond have also become known. Barium titanate with tin is, for instance, said to be higher than diamond, wherein it is to be anticipated that this material will, in future, be less expensive than diamond because of its producibility. In addition to the material of the cutting tool, the respective cutting geometry is decisive for the cutting performance to be achieved. A cutting geometry is defined by the shape of the chisel bit, on the one hand, and by the peripheral force occurring on the chisel bit and the rock-dependent normal force, on the other hand. In order to optimize a cutting system, i.e.

3 in order to largely reduce bending forces on the cutting chisel, the cutting geometry should be devised such that a resulting cutting force that coincides with the cutting axis, i.e. the axis of the chisel, will form. In this respect, it is to be taken care that the cutting geometry, due of the wear of the cutting insert, does not change to the effect that a resulting cutting force enclosing an angle with the chisel axis will form, which will result in a tilting load or tilting movement of the chisel and, in particular, the chisel base body. Cutting tests have demonstrated that cutting inserts coated with diamond composite materials involve the disadvantage that the wear layer will chip off within a very short time such that the originally defined and optimized cutting geometry will no longer be provided. Better results have been achieved with cutting inserts comprised of the diamond composite materials described in the documents W088/07409 Al and W090/01986 Al, since the wear is crucially reduced because of the improved wear properties and any possible wear will occur uniformly such that the cutting geometry will not be substantially changed. These basic considerations have led to the conclusion that, in order to maintain a constantly high cutting performance, it will be of essential importance to use a cutting insert that is completely made of a diamond composite material as is, for instance, the case with the subject matter of EP-1283936 B1, while, at the same time, selecting a cutting geometry by which tilting moments on the cutting insert or the tool base body will be avoided as largely as possible. The invention, therefore, aims to provide a cutting geometry that is devised for the described cutting inserts made of diamond or a diamond composite material and that is optimized so as to improve the cutting performance, wherein the service lives 4 of the cutting tools are, at the same time, extended at a possibly unchanged cutting geometry. To solve this object, the invention, departing from a cutting device of the initially defined kind, essentially consists in that the cutting tool is oriented on the tool carrier at an incident cutting angle of 45-58*, preferably 47-54', preferably 49*, and the tip of the cutting insert is substantially conically designed, with the nose angle being 60-75'. By incident cutting angle, the angle between the axis of the cutting tool or cutting insert, respectively, and the tangent to the circle swept by the tip of the cutting insert at a rotation of the cutting device, in particular shearer drum, is to be understood. The nose angle is the angle between two diametrically opposite generatrices of the cone of the cutting insert tip. The cutting geometry according to the invention results in a cutting tool orientation that is optimized in regard to the cutting performance, whereby the so-called clearance angle y, i.e. the angle between the rock face to be worked and the cutting tool blade, can at the same time be kept within the limits required to achieve a high cutting performance. Unlike with cutting inserts made of conventional hard-metal materials, wear phenomena need hardly, or not at all, be taken into consideration with cutting inserts made of diamond composite materials when devising the cutting geometry, since wear will hardly occur. By contrast, with cutting inserts made of conventional hard-metal materials it had to be taken into account, when devising the cutting geometry, that the rapidly occurring wear during the cutting of hard, abrasive rock caused a flattening of the original nose angle, and hence an enlargement of the contact surface of the cutting insert, which in turn led to an increase in the normal force of cutting. After 5 a certain operating period, the original cutting geometry was thus no longer ensured and led to a decrease of the cutting performance. With cutting inserts made of hard-metal materials, a smaller incident angle of, in particular, 450 had to be selected from the start in order to compensate for such phenomena. Now, if and when a homogenous diamond cutting insert is used according to the invention, the incident cutting angle can be selected to be larger than with hard-metal materials. According to the invention, the incident angle is, however, upwardly limited, on the other hand. If the cutting angle is, in fact, selected within a range larger than 600, the direction of the resulting cutting force will again be shifted, thus resulting in a bending load on the cutting chisel and a tilting load on the cutting holder in the other direction. Particularly optimum conditions on the contact point between the chisel tip and the rock will result, if the tip of the cutting insert has a tip radius of 2-5 mm, preferably 4 mm, as in correspondence with a preferred further development. A particularly advantageous configuration will result, if the cutting insert comprises a cylindrical base body having a diameter of preferably 10-18 mm and carrying the conical tip, wherein a transition radius of 35-45 mm, preferably 40 mm, is provided between the cylindrical base body and the conical tip. When using cutting inserts completely comprised of diamond composite materials, the additional problem of a sufficiently stable connection of the cutting insert with the tool base body will arise. Due to the atomic bonds of diamonds, the latter cannot be readily wetted and bonded with conventional soldering materials. High soldering temperatures, moreover, bear the risk 6 of a possible damage to the diamonds and, in addition, can lead to a decomposition of the diamonds on the interface with the soldering material because of the formation of corresponding reaction layers. The cutting device according to the invention in this respect is preferably further developed such that the diameters of the cutting insert and the receiving bore are dimensioned such that the cutting insert is held in the receiving bore by a shrink press fit. This further development is based on the surprising finding that shrink-press fits in cutting inserts made of diamond composite materials will provide sufficient retaining forces and enable a durable and stable fixation of the cutting inserts even at extremely high loads on the cutting tool, for instance when cutting hard rock. In this respect, a further improvement of the fixation will result according to a preferred further development in that the cutting insert is additionally held in the receiving bore by the aid of a soldered joint, preferably by using a solder, preferably a metal solder, introduced into the receiving bore, wherein a particularly stable connection will be achieved on the interface between the cutting insert and the solder, if the cutting insert comprises an electrolytic copper coating whose thickness is preferably between 0.1 and 0.2 mm, as in correspondence with a further preferred configuration. The solder and, in particular, the electrolytic copper coating of the cutting insert are incipiently melted when soldering the cutting insert in the bore of the tool base body, wherein the cooling of the tool base body and the thus formed shrink-press fit of the cutting insert in the receiving bore will cause the incipiently melted solder or electrolytic copper coating to penetrate into the surface of the cutting insert, thus forming kind of a micro-gearing between the tool base body and the cutting insert, which will result in an extremely strong and durable connection between the cutting 7 insert and the tool base body. In this respect, a copper-silver solder is preferably chosen as said solder. According to a preferred further development, the diamond composite material is comprised of diamond crystals that are interconnected by a silicon carbide matrix. Such a diamond composite material has become known from W090/01986 Al. A method for manufacturing such a diamond composite material has become known from W088/07409 Al. For manufacturing a cutting tool and, in particular, fixing a cutting insert of a diamond composite material in a receiving bore of a tool base body, a method comprising the following method steps can be used: a) heating of the tool base body to a temperature of at least 750 C, preferably 800-860'C, b) inserting of the cutting insert into the receiving bore of tool base body, c) cooling of the tool base body in air to about 6000C, d) further cooling of the tool base body with water, and, e) preferably, final tempering to about 3000C, wherein the cutting insert is fixed in the receiving bore of the tool base body by a shrink-press seat due to the heating and subsequent cooling of the tool base body. According to a preferred method control, it is further provided that electrolytic copper coating of the cutting insert is performed prior to step a), and that a solder, particularly a copper-silver solder, is introduced into the receiving bore between steps (a) and (b) such that the fixation of the cutting insert in the receiving bore is ensured both by the shrink-press seat and a soldered joint. In a preferred manner, the solder is introduced into the receiving bore in the form of a cartridge.

8 Overall, the configuration according to the invention ensures applicability in highly abrasive rock up to 165 MPa. Sparking during the cutting procedure can, moreover, be completely avoided. Besides, a substantial reduction of dust development takes place. The cutting forces can be reduced by about 50%. As opposed to hard-metal cutting inserts, a service life 30 times longer has been achieved. Further advantages, moreover, comprise an enhanced cutting performance as well as a reduced development of noise and heat, particularly when cutting hard rock. In the following, the invention will be described in more detail by way of exemplary embodiments schematically illustrated in the drawing. Therein, Fig. 1 illustrates, in a side view, a cutting insert made of a diamond composite material; Fig. 2 depicts a cutting tool having a diamond composite cutting insert inserted therein; and Fig. 3 illustrates the cutting geometry of a cutting tool according to the invention, which is fastened to a shearer drum. In Fig. 1, a cutting insert made of a diamond composite material is denoted by 1, which is basically comprised of three parts: a cutting insert tip 2, a cutting insert base body 3 and a cutting insert end 4. The whole cutting insert is rotationally symmetric about a central axis 10. Accordingly, the cutting insert tip is substantially conical with its tip rounded off. The tip radius denoted by r is between 2 and 5 mm and the nose angle a, i.e. the angle between the two diametrically opposite generatrices of the cone, in this configuration is 710. Fig. 2 depicts a tool base body 5 in which a cutting insert 1 is fixed in a receiving bore 6. The chisel, which is comprised of the tool base body 5 and the cutting insert 1, is rotationally 9 symmetric about the central axis 10. On its front end, the tool base body comprises a widening portion 7 directly transitioning into an apron 8. The conical widening in the front region of the round-shaft chisel serves to stabilize the cutting tool. On the rear end of the chisel is provided a groove 9, into which a snap ring (not illustrated) can engage for fixation to a chisel holder. Fig. 3 schematically depicts a shearer drum 12 to which a round shaft chisel is fixed via a chisel holder 11. The apron 8 abuts on the front side of the chisel holder, thus sealing the opening of the chisel holder against the penetration of dust and rock. The radius R corresponds to the distance between the rotational axis of the shearer drum and the tip of the cutting insert engaged with the rock or mine face 13. The so-called clearance angle y is defined as the angle of the free space between the tangent to the circle R (rock face) and the cutting tool blade (closest generatrix of the cutting insert tip) . The incident cutting angle P is defined as the angle between the central axis 10 of the chisel and the tangent to the circle with the radius R on the point of engagement. It is, in fact, the circle that is swept by the tip of the cutting insert at a revolution of the shearer drum 12. In the illustrated case, this angle amounts to 51*.

Claims (8)

1. A cutting device for a mining machine, in particular a shearer, including a tool carrier, in particular a shearer drum, that is rotatably mounted about a rotational axis and at least one cutting tool that is fixed to the tool carrier and comprises a tool base body and a cutting insert made of a diamond composite material or a harder material and fixed in a receiving bore of the tool base body, characterized in that the cutting tool is oriented on the tool carrier at an incident cutting angle (@) of 45-58*, preferably 47-54", preferably 490, and the tip (2) of the cutting insert (1) is substantially conically designed, with the nose angle being 60-75'.

2. A cutting device according to claim 1, characterized in that the tip (2) of the cutting insert (1) has a tip radius of 2-5 mm, preferably 4 mm.

3. A cutting device according to claim 1 or 2, characterized in that the cutting insert (1) comprises a cylindrical base body (3) having a diameter of preferably 10-18 mm and carrying the conical tip (2), wherein a transition radius of 35-45 mm, preferably 40 mm, is provided between the cylindrical base body (3) and the conical tip (2).

4. A cutting device according to claim 1, 2 or 3, characterized in that the diameters of the cutting insert (1) and the receiving bore (6) are dimensioned such that the cutting insert (1) is held in the receiving bore (6) by a shrink-press fit.

5. A cutting device according to any one of claims 1 to 4, characterized in that the cutting insert (1) is held in the receiving bore (6) by the aid of a soldered joint, preferably by 11 using a solder, preferably a metal solder, introduced into the receiving bore (6).

6. A cutting device according to claim 5, characterized in that the cutting insert (1) comprises an electrolytic copper coating whose thickness is preferably between 0.1 and 0.2 mm.

7. A cutting device according to claim 6, characterized in that a copper-silver solder is chosen as said solder.

8. A cutting device according to any one of claims 1 to 7, characterized in that the diamond composite material is comprised of diamond crystals that are interconnected by a silicon carbide matrix.