EA016249B1 - Rock-destroying tool and cutter therefor - Google Patents

Abstract

A group of inventions relates to mining machinery, in particular, to cutting tools of executive elements in mining machines used mainly for excavation of salts and coals free of hard inclusions and for fixing thereof. A rock-destroying device is characterized in that a wedge has toothed projections located in toothed recesses made on the cutting tool surface being in contact with the wedge, besides the wedge is pressed by a spring towards narrowed portion in a cutting tool holder. The cutter is embodied symmetrical relative to two mutually perpendicular planes the line of crossing of which coincides with the longitudinal axis of the cutter and the toothed recesses are disposed at two mutually-opposite surfaces of the cutter holder tail portion. A hard-alloy plate can be fixed either directly in the front portion of the cutter holder or in an insert arranged in the front portion of the cutter holder and made from a material of higher hardness compared to a holder material. The proposed invention reduces power consumption of a rock-destroying operation, provides higher economy of cutters and their regrinding, increases fatigue strength of a tangential cutter with simultaneous reliable play-free cutter fixture to the executive member in mining machines with an adjustable outlet thereof

Description

The group of inventions relates to the mining industry, namely to cutting tools of the executive bodies of mining machines, used mainly for the development of salts and coals without strong inclusions and their fastening.

Known tangential cutter D6 with a positive front angle of 18 ° (Cutting tool. Catalog of the Krasnoluchsk Machine Plant. Publishing House Voroshilovgrad truth, 1976). The advantages of this cutter include the symmetry of the holder in two mutually perpendicular planes, which allows it to be used up to the first regrind in two, and sometimes in three positions: after the wear of one face, the cutter is rotated 180 ° around its axis, after wear of the second face sometimes rotate 180 °.

The disadvantages of the D6 cutter include the fact that the conical fastening does not exclude losses that can reach up to 20%, as well as the complexity of the regrinding - the diameter of the carbide insert at D6 is 14 mm and when grinding, a lot of hard alloy has to grind. In addition, the D6 cutter has a fixed overhang of 48 mm and cannot be changed for a specific cutter, which is acceptable for chip thicknesses up to 30, maximum 35 mm. An increase in overhang with the same cone mount will result in large incisor losses.

Closest to the proposed invention is a rock cutting tool (AS USSR 1640405 A1, publ. 1988), including a cutter, a wedge retainer located on the rear side of the cutter, and a tool holder with a wedge groove. The cutter and the wedge have serrated protrusions and depressions along the entire length of the surfaces in contact with each other. The wedge is pressed towards the narrowed part of the wedge-shaped groove by means of a spring. In this technical solution, the cutter with the wedge are arranged radially, and the cutter abuts its wedge against the wedge without experiencing bending loads.

The advantage of such a fastening should also include the ability to extend the cutter during its wear, moving it relative to the wedge.

The disadvantage is the presence of gear depressions made along the entire length of the tool holder and especially located near the front (front) surface of the tool holder - in the region of maximum bending moment and, being stress concentrators, are a factor that reduces the fatigue strength of the tool holder.

Another disadvantage is the need for regrinding of the incisor after each blunting, as well as the wedge arrangement adopted in the device behind the incisor practically eliminates the installation of the incisor tangentially so as to have a positive rake angle. When destroying weak media (salts and coals), tangentially setting the cutter at an angle to the direction of cutting makes it possible to give the cutter a positive front angle tangentially, which is necessary to reduce the energy intensity of fracture, as well as reduce the bending force on the holder by approaching the cutter axis to the resultant cutting force and filing.

The technical task of the proposed group of inventions is to reduce the energy consumption of rock destruction, to increase savings in consumption and regrinding of cutters, to increase the fatigue strength of a tangential cutter by eliminating depressions in the place of the highest loads on the tool holder while ensuring reliable and backlash-free mounting of the cutter on the executive organ of the mining machine with adjustable the size of its departure.

The problem is solved in that in a rock cutting device containing a tool holder with a wedge-shaped groove in which the wedge and cutter are located, the wedge is made with gear protrusions located in the gear cavities made on the surface of the cutter in contact with the wedge, while the wedge is preloaded using a spring in side of the narrowed part of the wedge-shaped groove, the feature is that the cutter is symmetrical about two mutually perpendicular planes, the intersection line of which coincides with the longitudinal axis of the cutter, jagged depressions arranged on two mutually opposite surfaces of the tail portion of the toolholder.

In addition, the tooth depressions are located on a plot of no more than 1/3 of the length of the incisor from the end of the tail of the incisor.

In addition, a wedge is located between the front of the tool holder and the front plane of the wedge-shaped groove of the tool holder.

In addition, the wedge groove is located at an angle of 35-45 ° to the cutting direction.

The task is also solved by two options for performing incisors.

In the first embodiment, mainly used for shavings of small thickness (30-35 mm), the cutter contains a holder, on the surface of which is in contact with the wedge, tooth cavities are made, and a carbide plate fixed directly to the front of the holder. A feature is that the cutter is made symmetrical with respect to two mutually perpendicular planes, the intersection line of which coincides with the longitudinal axis of the cutter, and the tooth depressions are located on two mutually opposite surfaces of the tail of the cutter holder.

In addition, the carbide plate is placed in the slotted groove made in the front of the holder.

In addition, the tooth depressions are located on a plot of no more than 1/3 of the length of the incisor from the end of the tail of the incisor.

- 1 016249

In the second embodiment, used mainly for chips of large thickness (70-90 mm), the cutter contains a holder, on the surface of which is in contact with the wedge, gear cavities and a carbide plate are made. A feature is that the cutter is made symmetrical with respect to two mutually perpendicular planes, the intersection line of which coincides with the longitudinal axis of the cutter, and the tooth cavities are located on two mutually opposite surfaces of the tail of the tool holder, while the carbide plate is fixed in the insert located in the front of the tool holder and made of a material of greater hardness compared to the toolholder material.

In addition, the insert is made with a length of not more than 1/3 of the length of the cutter.

In addition, at one end the insert is located in the groove in the front of the holder and welded to it, and at the other end of the insert there is a slotted groove in which the carbide plate is placed.

In addition, the tooth depressions are located on a plot of no more than 1/3 of the length of the incisor from the end of the tail of the incisor.

The alleged invention is illustrated by drawings.

In FIG. 1 shows a section of the proposed rock cutting device for working with chips with a thickness of 30-35 mm

In FIG. 2 shows a section of the proposed rock cutting device for working with chips with a thickness of 70-90 mm

In FIG. 3 shows a wedge.

In FIG. 4 shows a tool for working with chips with a thickness of 70-90 mm.

In FIG. 5 shows a cutter for working with chips with a thickness of 30-35 mm.

In the tool holder 1, a wedge-shaped groove is made, oriented at an acute angle of 35-45 ° to the cutting direction. A wedge 2 and a cutter 3 are located in the groove. Cutter 3 is symmetrical about two mutually perpendicular planes, the intersection line of which coincides with the longitudinal axis of the cutter, for example in the form of a rectangular parallelepiped, and is installed tangentially - at an angle to the direction of cutting, usually at an angle of 35-45 °. The wedge 2 is located between the front face of the cutter 3 and the front plane of the wedge-shaped groove of the tool holder 1. The contacting surfaces of the wedge 2 and the cutter 3 are made with gear protrusions 4 and gear cavities 5, respectively, and the section with gear protrusions 4 is made protruding relative to the remaining part of the surface of the wedge 2 in contact with the cutter 3, and sections with gear dents 5 of the cutter are made on two mutually opposite surfaces of the cutter in its tail part recessed with respect to the remaining part of the surface 3, in contact with the wedge, so that the tips of the teeth are in the same plane with the rest of its mating surface.

To reduce the effect of the tooth cavities on the fatigue strength of the tool holder 3 in the proposed device, the tooth section of the surface of the tool 3 is made on its tail and has a length from its rear end not exceeding 1/3 of the length of the tool 3, and accordingly the protruding tooth section of the wedge 2 is made in tail (thin) of its part.

The shape of the protrusions and depressions may be acute-angled, trapezoidal, or some other, convenient device, technologically advanced in manufacture and creating the smallest concentrators, undesirable from the point of view of its fatigue strength.

In the tool holder 1, in a special slot, a spring 6 is placed, one end of which is fixed in the case of the tool holder 1, and the other end abuts the pin 7, made in the tail (thin) part of the wedge 2. The spring 6 tightens the wedge 2 together with the cutter 3, paired with a wedge by means of gear protrusions and depressions, into the narrow part of the wedge-shaped groove of the tool holder 1. The cutter 3, thus, is jammed without a gap. The wedge 2 and, accordingly, the wedge-shaped groove of the tool holder 1 are made with an angle of 8 °, the tangent of which is approximately equal to the coefficient of friction of steel over steel. The tooth sections on the wedge 2 and on the cutter 3 are made with the same pitch, approximately equal to 2-3 mm. When executed with a smaller step, the cutter is pushed by the workloads, a larger step leads to an undesirably large interval of change in the tool overhang.

The use of incisors symmetrical in two mutually perpendicular planes in wedge-mounted tool holders is decided by making dents 5 on two opposite surfaces of the tool holder 3 — in their tail.

In the embodiment of the cutter 3 for working with small chips - up to 30-35 mm, the carbide plate 8 is placed in a slotted groove made directly in the front of the holder (Fig. 1 and 5).

In general, the abrasion of the front edge of the incisor by the destroyed material in symmetrical incisors is a positive fact. When the cutter is rotated 180 °, the front (raised) face, when turning, the back face will not abut the face. The cutter will be self-sharpening. But, when the wear of the front face is very large, which is typical when working with chips of large thickness - up to 7590 mm, the carbide plate will be exposed, and when rotated through 180 ° it can break. The use of thin plates in cutters of a symmetrical design leads to the need to protect these plates from washing out by the destroyed rock, when, due to the large cutting force, the front face, which is not protected by a hard alloy, is abraded. For this, the cutter 3 is performed with a wear-resistant insert 9

- 2 016249 (Fig. 2, 4). When the hardness of the holder material is 48-50 IKS (for example, from 35KhGSA steel), the insert is made with a hardness of 55-60 NKS (for example, from steel P6M5, P9). It is done like this. An insert 9 with a length of 40-50 mm from wear-resistant steel with a diameter 2-3 mm larger than the width of the carbide plate, is welded at one end (for example, by friction to the main holder (for example, from 35KhGSA steel)), and the other end of the insert is reinforced with carbide plate 8 by placing the latter in the slotted groove made in front of the insert 9.

The rock-breaking device operates as follows.

The wedge 3, compressing the spring 6, is pulled into the widened part of the wedge-shaped groove of the tool holder 1, then the cutter 3 is inserted into the wedge-shaped groove and pressed against the wedge 2, mating the tooth section on one of its surfaces with the tooth section located on the wedge 2. After that, the wedge 2 is released, and the spring 6 pulls it together with the cutter 3 into the narrowed part of the wedge-shaped groove of the tool holder 1. The cutter 3, when it is mated with the wedge 2, can be advanced or retracted. Depending on this, the part of the cutter 3 protruding from the tool holder 1 (its extension) can be longer or shorter. This is a significant advantage of such a mount. Mining machines with different power-to-weight ratio can remove (chip, cut) chips of greater or lesser thickness. Accordingly, the departure of the cutter on the executive body of the machine, it is advisable to have more or less. In addition, as a result of regrinding of a blunt incisor, it is shortened. Shortening can be significant, for example, with a cutter 3 with a carbide plate 1.5–2 mm thick and up to 30 mm long, shortening can reach 15–18 mm. To maintain the desired departure, the cutter shortened after regrinding can be extended by moving along the gear surface relative to the wedge.

To install the cutter 3 in a new position, the wedge 2 with the cutter 3 is moved to a wider part of the tool holder 1, as a result of which the protrusions on the wedge 2 come out of the depressions on the cutter 3, after which the cutter 3 can be moved along the wedge 2 or rotated 180 °. When the cutter 3 is rotated 180 °, it is mated by another gear section located on its opposite surface, with a gear section on the wedge 2, as a result of which the front (worn) face of the cutter 3 is the rear face, which will not abut the face.

The technical result of the proposed group of inventions is the following:

reduction of the energy intensity of destruction due to bladeness (in comparison with RKS cutters), as well as through the use of cutters with inserts of increased wear resistance when switching to work with large thicknesses of chips;

reduction in incisor consumption. With symmetrical cutters and a wedge mount, which allows you to extend the cutters shortened due to wear, you can use long carbide inserts;

rigid (backlash-free) fastening significantly lengthens the life of toolholders and, therefore, increases the overhaul life of the executive body of machines.

Claims (11)

CLAIM 1. A rock breaking device comprising a tool holder with a wedge-shaped groove in which the wedge and cutter are located, the wedge is made with serrated protrusions located on the tooth cavities made on the surface of the cutter in contact with the wedge, and the wedge is pressed with a spring towards the narrowed part of the wedge-shaped groove characterized in that the cutter is made symmetrical with respect to two mutually perpendicular planes, the intersection line of which coincides with the longitudinal axis of the cutter, and the gear depressions are located on two mutually opposite surfaces of the tail of the tool holder. 2. The device according to claim 1, characterized in that the tooth depressions are located on a section with a length of not more than 1/3 of the length of the cutter from the end of the tail of the cutter. 3. The device according to claim 1, characterized in that the wedge is located between the front of the tool holder and the front plane of the wedge-shaped groove of the tool holder. 4. The device according to claim 1, characterized in that the wedge groove is located at an angle of 35-45 ° to the cutting direction. 5. A cutter comprising a holder, on the surface of which gear cavities are made, and a carbide plate fixed directly to the front of the tool holder, characterized in that the cutter is symmetrical with respect to two mutually perpendicular planes, the intersection line of which coincides with the longitudinal axis of the cutter and the gear cavities located on two mutually opposite surfaces of the tail of the tool holder. 6. The cutter according to claim 5, characterized in that the carbide plate is placed in the slotted groove made in the front of the holder. 7. The cutter according to claim 5, characterized in that the tooth depressions are located on a plot of no more than 1/3 of the length of the cutter from the end of the tail of the cutter. 8. A cutter containing a holder, on the surface of which gear cavities are made, and a carbide plate, characterized in that the cutter is made symmetrical with respect to two mutually perpendicular planes, the intersection line of which coincides with the longitudinal axis of the cutter, and the cog - 3 016249 hollows are located on two mutually opposite surfaces of the tail of the tool holder, while the carbide plate is fixed in the insert located in the front of the tool holder and made of a material of greater hardness compared to the material of the tool holder. 9. The cutter according to claim 8, characterized in that the insert is made with a length of not more than 1/3 of the length of the cutter. 10. The cutter according to claim 8, characterized in that at one end the insert is located in the groove in the front of the holder and welded to it, and at the other end of the insert there is a slot groove in which the carbide plate is placed. 11. The cutter according to claim 8, characterized in that the tooth depressions are located on a plot of no more than 1/3 of the length of the cutter from the end of the tail of the cutter.