RU85383U1 - REPLACEABLE MULTI-DIMENSIONAL CUTTING PLATE - Google Patents

Abstract

1. A replaceable multifaceted cutting insert with reinforcing chamfers along the cutting edges and alternating-profile chip-cutting surfaces, characterized in that as the distance from the vertices of the working parts of the cutting insert is removed, the shape of the front surface adjacent to the chamfer changes from convex to concave with the centers of curvature located respectively below and above the front surface of the tool, the value of the front angle decreases, and the height and angle of inclination of the chip-cutting ledges increase. ! 2. The interchangeable multifaceted cutting insert according to claim 1, characterized in that the cross-sections of the sections of the chip-cutting surfaces adjacent to the chamfer have the shape of circular arcs, and as the distance from the vertices of the plate increases, the curvature of the chip-cutting surface on its convex section decreases and increases on the concave one. ! 3. Replaceable multifaceted cutting insert according to claim 1, characterized in that the height of the side faces of the working sections of the plate decreases with distance from the vertices. ! 4. The replaceable multifaceted cutting insert according to claim 1, characterized in that on the front surface of the insert, chip-forming elements are made in the form of dome-shaped protrusions located along the cutting edges and spaced from them at a distance of no more than a seven-fold bevel width. ! 5. Replaceable multifaceted cutting insert according to claim 1, characterized in that the insert is made with rounded cutting edges. ! 6. Replaceable polyhedral cutting insert according to claim 1, characterized in that the reinforcing bevel is made of two-sided.

Description

The utility model relates to the field of processing by cutting ductile metals and alloys.

Known multi-faceted interchangeable inserts located along the cutting edges reinforcing chamfers and chip-cutting surfaces of variable profile [Kotani Vessels. A cutting insert with a chip-forming surface MF // Kikay-to-kogu, 1989, 73, No. 9, p.66-69.]. The geometrical parameters of the insert are set in such a way as to intensify the curling of the chip simultaneously in two planes - the front surface and normal to the cutting edge of the secant plane. When these rotational movements are combined, a spiral-shaped chip is formed, the axis of which lies in a plane parallel to the cutting plane.

The disadvantage of the plates is the limited ability to control the chip flow, since when using such plates, the direction of the axis of the chip can be adjusted in only one plane.

As a prototype, a multifaceted interchangeable cutting insert with variable-profile chip cutting surfaces located along the cutting edges is adopted, the cross-sectional shapes of which change along the cutting edges when moving away from its tip from a concave circular arc with a center located above the front surface of the tool to a convex arc with a center located below the front surface of the instrument [Patent 2237549 C1 Russian Federation, IPC ⁷ V23V 27/00. Replaceable cutting insert [Text] / S.V. Mikhailov, D.S. Skvortsov. - No. 2003105381/02; declared 02/25/2003; publ. 10/10/2004, Bull. No. 28. - 24 p.]. The plate allows you to improve the removal of chips from the cutting zone due to the intensification of curling in the plane of the cross-section of the chip.

The disadvantages of the prototype are limited technological capabilities associated with a relatively narrow range of possible changes in cutting conditions and low efficiency of chip breaking. The area of use of the plate is limited by the size of the chip-cutting groove in the region of the tip of the tool (the thickness a _{1 of the} material layer to be cut should not exceed five times the radius of the groove). The low reliability of chip control is due to the fact that when cutting with a plate, the direction of movement of the chip spiral coincides with the rotation of the workpiece. As a result, the bending deformation of the chip from interaction with the workpiece and tool is insufficient for crushing it.

The objective of the utility model is to expand the technological capabilities of the cutting insert and increase the reliability of chip control during the processing of plastic materials.

The technical result is achieved by the fact that on a plate with reinforcing chamfers along the cutting edges and chip-forming surfaces of a variable profile, the shape of the front surface adjacent to the chamfer changes from a convex to a concave surface with curvature centers located respectively below and above the front surface of the tool, the value of the front angle decreases, and the height and angle of inclination of the chip cutting ledges increase.

In order to increase the manufacturability of the cutting insert, the cross-sections of the chip-cutting surface adjacent to the chamfer are made in the form of arcs of circles whose curvature decreases with increasing distance from the tip of the insert, but increases on the concave.

To increase the working capacity of the plate and the reliability of chip breaking, the height of the side faces of the working sections of the plate decreases with distance from the vertices, and chip-forming elements in the form of dome-shaped protrusions located along the cutting edges and spaced no more than seven times the chamfer width are performed on the convex concave surface of the groove.

The cutting insert can have a rectangular, triangular, rhombic and other shapes, can be made with a zero and a positive rear angle, with rounded cutting edges and a two-sided reinforcing chamfer.

Increasing the efficiency of the plate occurs due to a change in the shape of the chips generated during cutting, the direction of its movement and the interaction scheme with the workpiece. The creation of a variable rake angle, synchronously changing together with the radius of curvature of the chip-cutting surface, the height and angle of inclination of the chip-cutting ledges, intensifies the additional curling of the chip in the plane of its cross section, as a result of which the conditions for the interaction of the chip with the workpiece, causing an increase in its deformation and, as a result, chip control reliability. An increase in the rigidity of the chip and the reliability of its crushing occurs when a curved cutting edge with a variable angle λ is created on the plate. The variable angle λ improves the conditions for inserting the tool into the workpiece, which favorably affects its performance.

Expanding the technological capabilities of the proposed designs of cutting inserts and increasing the reliability of chip control during their operation is associated with an improvement in the process of chip formation and ensuring rational control of the direction of chip exit from the tool by creating a special shape of the tool’s front surface with curvature varying along the cutting edge. The plate is made in such a way that the rear walls of the chip-cutting surface are removed from the top of the plate. Thus, the plate can be used in the processing of materials with different feed values. During operation of the plate, favorable conditions are created for additional rotation of the cross section of the chip and changes in the trajectory of its initial movement. Unlike the prototype, the shavings begin to move not down under the cutter, but up, abutting against the surface of the workpiece. By friction with a rotating workpiece, the chip is additionally deformed and breaks. By controlling the gradient of changes in the geometric parameters of the tool along its cutting edge, it is possible to adjust the shape and length of the chip segments. The chip breaking efficiency can be improved by creating domed protrusions on the front surface that further deform the contact layers.

Figure 1 shows a square interchangeable cutting insert with chip-cutting surfaces of variable profile, axonometry; figure 2 is a drawing of a plate with sections in the main secant planes.

The cutting insert has side faces 1, a reinforcing chamfer 2, chip-cutting surfaces 3, curved cutting edges 4, chip-forming protrusions 5, chip-forming elements 6. The chip-cutting surface is made in such a way that its cross-sections, when removed from the top of the insert 7, change from a convex to a concave shape with centers of curvature located respectively below and above the front surface of the tool. The surfaces are located along the cutting edges and are adjacent to the chamfer. As you move away from the vertices of the plate, the curvature of the chip-cutting surface 1 / R _k on its convex section decreases, but on the concave it increases, the rake angle γ decreases, and the height h and the angle of inclination ψ of the chip-cutting ledges increase (Fig. 2):

In addition, the height of the side surface of the plate with distance from its top to the middle of the cutting edge decreases

The radius of curvature of the convex part of the chip-cutting surface at the top of the cutter R _{0 is} chosen depending on the purpose of the plate. The value of the minimum radius of curvature of the chip-cutting surface, located in the region of the top of the plate, depends on the thickness a _{1 of the} sheared material layer. Its value is taken from the range R ₀ ≥ (5 ... 10) and ₁ . For rough operations, the value of R _{0 is} greater than for finishing operations.

Depending on the cutting conditions, the chamfer 2 can be made flat or dihedral, with a constant or variable rake angle along the cutting edge. To increase the strength of the insert, its cutting edge is rounded (see section G-G in Fig. 2). On the chip cutting surface 3, a series of chip deforming elements 6 are made. The element profile is shown in section BB in FIG. 2.

The length l _{a of the} working (active) portion of the cutting edge of the insert depends on its shape. For a square plate and a plate of a rhombic shape with an angle at the apex of 80 ° l _a = 2l / 3; for a triangular insert and a rhombic insert with an apex angle of 55 °, l _a = l / 2, where l is the length of the cutting edge of the insert.

The intensity of the curling of the chips in three mutually perpendicular planes depends on the degree of change in the curvature of the chip-cutting surface along the main cutting edge of the tool, the rake angle, the shape and position of the chip-cutting ledges on the plate.

The cutting insert operates as follows. The metal layer to be cut falls onto a chip-forming surface adjacent to the chamfer of complex shape.

As a result of various conditions of contact between the chips and the tool, a stress-strain state of the cutting zone is nonuniform across the width of the sheared layer, as a result of which the longitudinal layers of the chip take a different shape at the exit from it. The chip layers formed at the top of the plate curl less intensely in the main secant plane of the tool. Layers of chips moving along a groove with a concave profile curl to a greater extent. The condition for optimal chip formation is fulfilled by creating a chip-cutting surface on the plate with a curvature variable along the cutting edge, decreasing as the rake angle moves away from the plate vertices, increasing the height and angle of inclination of the chip-cutting ledges.

Inhomogeneous deformation of the chip leads to the fact that in addition to its rotational movements in the plane of the front surface and normal to the cutting edge of the plane, the chip receives an additional transverse rotation, changing its shape and direction of the initial gathering. The chips take the form of a spiral spiral moving in the opposite direction to the rotation speed of the workpiece. Due to the additional deformation of the chips when interacting with the elements of the SPIZ system that limit its natural trajectory, the reliability of crushing the drain chips into parts increases. The expansion of technological capabilities of the cutting insert is associated with a change in the chip deformation pattern, in which the chip-cutting ledge is located at a distance from the top of the insert.

The use of the plate allows to increase the efficiency of machining plastic metals and alloys by expanding the functionality of the cutting plate and reducing downtime of automated equipment associated with the formation of a chip shape unfavorable for the normal flow of the technological process.

Claims (6)

1. A replaceable multifaceted cutting insert with reinforcing chamfers along the cutting edges and alternating-profile chip-cutting surfaces, characterized in that as the distance from the vertices of the working parts of the cutting insert is removed, the shape of the front surface adjacent to the chamfer changes from convex to concave with the centers of curvature located respectively below and above the front surface of the tool, the value of the front angle decreases, and the height and angle of inclination of the chip-cutting ledges increase. 2. The interchangeable multifaceted cutting insert according to claim 1, characterized in that the cross-sections of the sections of the chip-cutting surfaces adjacent to the chamfer have the shape of circular arcs, and as the distance from the vertices of the plate increases, the curvature of the chip-cutting surface on its convex section decreases and increases on the concave one. 3. Replaceable multifaceted cutting insert according to claim 1, characterized in that the height of the side faces of the working sections of the plate decreases with distance from the vertices. 4. The replaceable multifaceted cutting insert according to claim 1, characterized in that on the front surface of the insert, chip-forming elements are made in the form of dome-shaped protrusions located along the cutting edges and spaced from them at a distance of no more than a seven-fold bevel width. 5. Replaceable multifaceted cutting insert according to claim 1, characterized in that the insert is made with rounded cutting edges. 6. Replaceable multifaceted cutting insert according to claim 1, characterized in that the reinforcing bevel is made of two-sided.