SU1266664A1 - Cutting insert - Google Patents

Abstract

The invention relates to the field of metalworking, namely to a cutting tool for turning, milling and other machine tools. The purpose of the invention is to improve the operational characteristics (istik, is achieved by improving the cutting properties of the insert by creating an optimal geometry of the cutting part of the insert. The cutting insert is a rim of a multi-faceted shape, which has a rhombic profile in cross section and is jumpered along the inner perimeter the transverse direction — the ribs, the section of the Kizmi insert on the chambers. The outer surfaces of the ribs mate with the outer edges of the rhomboid profile and can be positioned at an angle to jumper to increase the rake angle. In one of the insert chambers, a plate is made of more wear-resistant material than the insert material, for example, of mineral ceramics. The plate may be made of solid lubricant or another mother (L for various technological purposes. The diamond-shaped profile may have an asymmetrical shape with respect to the lintel, which allows for various types of work to vary the cut when the insert is flipped. 3 hp f-ly, 4 ill. tc about: O) O5 O) 4

Description

The invention relates to metalworking, in particular to a cutting tool for turning, milling and other metalworking machines.

The purpose of the invention is the improvement of operational characteristics is achieved by improving the cutting properties of the insert by creating the optimal geometry of the cutting part of the insert.

In FIG. 1 shows a tetrahedral cutting insert; in FIG. 2, section AA in FIG. 1; in FIG. 3 example of the use of inserts in work; in FIG. 4 - section BB in Fig.Z.

The cutting insert consists of a .1 rim of a multifaceted shape, having a diamond-shaped cross section and connected along the inner perimeter by a jumper 2, and in the transverse direction by ribs 3 dividing the insert into chambers. The outer surfaces of the ribs mate with the outer edges 4 of the rhomboid profile and can be positioned at an angle to the jumper to increase the rake angle.

The diamond-shaped profile can have an asymmetric shape relative to the jumper, which allows for various types of work to vary the cutting angles when turning the insert.

In one of the insertion chambers, a plate 5 of a more wear-resistant material is densely mounted than the insert material, for example, from mineral ceramic. The plate may be of solid lubricant or other material for various technological purposes. For ease of replacement of the plate, a hole 6 is made in the chamber jumper through which the plate is pushed out of the socket.

For turning the shaft 7, the insert is installed in the socket of the cutter 8 with an inclination for the formation of the rear angles and is pressed by the gripper 9.

The operation of the insert is as follows.

With a small allowance not exceeding the length of the chamber, the chips smoothly descend into the chamber at a large rake angle, abutting against a jumper or into an embedded plate made of wear-resistant material.

With a large allowance t exceeding the length of the chamber, in addition to the rim face, a nearby transverse rib is involved (see Fig. · 3). The conditions for the flow of chips along the rim face and on the surface of the ribs differ sharply due to a significant difference in the front angles: a large positive one along the rim face and negative along the edge. This contributes to the breaking of the chips into two streams 10 and 11, respectively, at a variable depth t, a rough outer surface and at a constant depth t ₂ with the outer crust removed. A rough allowance for the outer crust of the forgings or cast billets is removed by a rib. A negative rake angle enhances rib strength and provides brittle chip breaking.

In the case of a change in the height of the general allowance t, the rib is brought out to the level of the rough allowance for the crust t _{t by} turning the cutter in plan at an angle f; (see Fig. 3).

Chamber design insert-. Chip separation improves the technological support of the cutting process due to the insertion into the chambers of plates 5 of various technological purposes: antifriction, lubricating, chip breaking, combined.

The proposed insert can significantly improve cutting conditions due to the small angle of the cutting wedge J5 in the cross section of the rim, increase rigidity compared to open forms of inserts, improve heat transfer from the cutting edge due to a significant increase in surface compared to solid inserts of the same size. The ribs, in addition to increasing the rigidity of the insert, increase the cooling surface.

The presence of a jumper and a insert plate provides a more efficient crushing of chips compared to the known chip breaking grooves on standard plates. A significant distance of the cutting edge to the jumper contributes to an increase ⁱⁿ the length of chip breaking and reduction of its rigidity, which increases the efficiency of breaking with a decrease in chip breaking force.

Reducing the cutting wedge in combination with a deep depression to the jumper, in addition to reducing the cutting force, creates an additional effect of developing a leading crack in front of the cutting wedge due to the chip stop in the bottom of the jumper and reverse bending. Varying the height of the profile to the bridge (asymmetry of the diamond-shaped 5 section), you can use the insert for different operating modes: with a low profile height on one side of the insert, fine turning, with a large profile height on the other side, 10 rough turning.

Claims (4)

The invention relates to metal working, in particular to a cutting tool for turning, milling and other metalworking machines. The purpose of the invention is to improve the performance characteristics by improving the cutting properties of the insert by creating the optimum geometry of the cutting part of the insert. FIG. Figure 1 shows a tetrahedral cutting insert; in fig. 2 section A-A in FIG. one; in fig. 3 An example of the use of an insert in a work; in fig. 4 - section B-B in FIG. 3 The cutting insert consists of a rim .1 of a multifaceted shape, having a diamond-shaped profile in cross section and connected along the inner perimeter by a jumper 2, and in the transverse direction by ribs 3 dividing the insert into chambers. The outer surfaces of the ribs mate with the outer edges 4 of the diamond profile and can be angled to the web to increase the rake angle. The diamond-shaped profile may have an asymmetrical shape with respect to the lintel, which allows, in relation to different types of work, to vary the cutting angles when the insert is flipped. In one of the insert chambers, the plate 5 is made of a more wear-resistant material than the insert material, for example, mineralocerite ki. The plate may be of solid lubricant or other material for practical technological purposes. For the convenience of replacing the plate in the lintel of the chamber, an opening 6 is made through which the plate is pushed out of the socket. For turning the shaft 7, the insert is positioned in the slot of the cutter 8 with an inclination to form the rear corners and is pressed by the clamp 9. The operation of the insert is as follows. With a small stock, which does not exceed the length of the chamber, the chips smoothly descend into the chamber at a large rake angle, resting against the jumper or into the nested plate of wear-resistant material. With a large seam allowance t, which exceeds the length of the chamber, in addition to the rim edge, the nearby transverse part is involved; rib (see fit 3). The conditions of chip flow along the edge of the rim and on the surface of the edge are sharply different due to a significant difference in the front corners: a large positive one on the edge of the rim and negative on the edge. This contributes to chip breaking into two streams 10 and 11, respectively, at a variable depth t | coarse outer surface and at a constant depth t ,, with the outer outer crust removed. The coarse seam allowance of the outer crust of the forging or cast billet is removed by an edge. A negative rake angle increases the strength of the ribs and ensures brittle breaking of chips. in the event of a change in the total allowance t, the rib is brought to the level of the rough allowance of the crust t by turning the cutter in the plan at an angle (see Fig. 3). In addition to dividing the chip, the chamber construction of the insert improves the technological support of the cutting process due to the insertion into the chambers of the plates 5 for various technological purposes: antifriction-free, lubricating, chip breaking, combined. The proposed insert makes it possible to significantly improve cutting conditions due to the small angle of the cutting wedge f in the cross section of the rim, to increase rigidity compared to open plate shapes, to improve heat dissipation from the cutting edge due to a significant increase in surface compared to solid plates of the same size. The ribs, in addition to increasing the stiffness of the insert, increase the cooling surface. The presence of a jumper and a base plate provides more efficient chip breaking compared to the known chip breaker grooves on standard plates. The considerable distance of the cutting edge to the lintel contributes to an increase in the length of the breaking of the chips and a decrease in its rigidity, which increases the efficiency of the breaking while reducing the chip breaking force. The reduction of the cutting wedge in combination with the deep depression to the web, in addition to reducing the cutting force, creates an additional effect in the development of a leading crack in front of the cutting wedge due to the cutting force of the chips in the bottom of the web and reverse bending. By varying the height of the profile to the lintel (asymmetry of the diamond-shaped section), an insert can be used for different modes of operation: with a small profile height on one side of the insert, fine turning, with a large profile height on the other side, rough turning. Claim 1. Cutting insert, having the form of a polyhedral rim, characterized in that, in order to improve performance, the rim has a diamond-shaped profile in cross section and is connected along the inner perimeter by a jumper, and in the transverse direction, it is provided with edges separating the insert on the chambers, while the outer surfaces of the ribs mate with the outer edges of the rhombus. 2. The insert according to claim 1, characterized in that, in order to effectively use the cutting edges along the length, the outer surfaces of the ribs are made at an angle to the web. 3. Insert on PP. 1 and 2, that the diamond profile has an asymmetrical shape with respect to the web. 4. Insert on PP. 1 - 3, that is, in at least one of the chambers a plate made of wear-resistant material is installed, and in the bridge under it is made. the hole. K-A 2 T fug.;.