CN114131064A

CN114131064A - Turning blade for small part machining

Info

Publication number: CN114131064A
Application number: CN202111416012.9A
Authority: CN
Inventors: 李东进; 庄艳江; 黄冬云; 谢家培; 王杰伟
Original assignee: Xiamen Golden Egret Special Alloy Co Ltd
Current assignee: Xiamen Golden Egret Special Alloy Co Ltd
Priority date: 2021-11-25
Filing date: 2021-11-25
Publication date: 2022-03-04

Abstract

The invention discloses a turning blade for machining small parts, which comprises a blade body; the insert body has an upper surface, a lower surface and side surfaces; a first bulge in a circular truncated cone shape and a second bulge in an inverted V shape are sequentially arranged in the direction from the front cutter surface to the middle part of the blade body corresponding to the arc cutting edge, and the first bulge and the second bulge are respectively in a symmetrical structure along the angle bisector of the acute angle part of the blade body; the first protrusion and the second protrusion respectively comprise a top surface and a side surface; the top surface of the first bulge is higher than the position of the arc cutting edge, and the top surface of the second bulge is higher than the position of the top surface of the first bulge. According to the invention, a specific convex structure is designed in the chip groove, so that a sufficient chip containing space is ensured, the sharpness of the cutter is enhanced, the effect of the cutter on chips is enhanced, the chips can be effectively controlled while small-feed small-cutting-depth machining and cutting-depth change of small parts are realized, and the service life of the cutter and the surface quality of a workpiece are improved.

Description

Turning blade for small part machining

Technical Field

The invention relates to the technical field of cutters, in particular to a turning blade for machining small parts.

Background

A tool is a tool used for cutting machining in machine manufacturing, and is also called a cutting tool. There are a wide variety of tools, including tools for machining various outer surfaces, tools for hole machining, tools for thread machining, tools for gear machining, tools for cutting, and so forth. The turning blade is a cutter for turning a rotating workpiece, small-diameter parts are typical workpieces in industries such as 3C, automobile, medical treatment, hydraulic pressure and the like, in the 3C and medical treatment industries, the small-diameter parts belong to high-precision and small-size products, the requirements on the size precision and the surface quality of the products are extremely high, the working condition of small feeding and small cutting depth is often adopted during processing, the processing difficulty is high, and therefore higher requirements are provided for the performance of the cutter.

Most of the cutters adopt high-strength three-dimensional groove design or two-dimensional groove design at the present stage. The high-strength three-dimensional groove is provided with a blade width and a large chip groove, so that the strength of the cutter is enhanced, the cutting resistance is reduced during large cutting depth, and the requirements of chip removal and chip breaking of small-diameter parts under the working conditions of small cutting depth and small feeding are difficult to meet. The chip groove designed by the two-dimensional groove is simple in structure and difficult to meet the requirements of chip removal and chip breaking of small-diameter parts under the working condition of variable cutting depth. As is well known, if the chip removal is good, the iron chips can take away most heat generated during machining, the influence of cutting heat on the cutter is reduced, and the abrasion of the cutter is delayed. Good chip breaking can prevent the chips from winding or damaging the cutter due to violent vibration, and the requirement of automatic processing is met. Therefore, designing a small part turning insert that can achieve stable machining with small cutting depth and small feed for small diameter workpieces is an urgent problem to be solved.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provide a turning blade for machining small parts, which ensures enough chip containing space, enhances the sharpness of a tool, strengthens the effect of the tool on chips, and can effectively control the chips during small-feed small-cutting-depth machining and cutting-depth change of small parts by designing a specific convex structure in a chip containing groove so as to improve the service life of the tool and the surface quality of a workpiece.

The technical scheme adopted by the invention for solving the technical problems is as follows: a turning blade for machining small parts comprises a blade body; the projection of the outline of the blade body is in a polygonal shape; the blade body having an upper surface, a lower surface and a side surface connected between the upper and lower surfaces; the middle part of the blade body is provided with a screw locking hole penetrating through the upper surface and the lower surface; at least one of the corners of the insert body is acute, and the upper surface and the side surface intersect to form a cutting edge in the acute corner of the insert body; the cutting edge comprises an arc cutting edge corresponding to the corner tip and a line segment cutting edge connected with two sides of the arc cutting edge; in the upper surface, a front tool face is formed by extending the cutting edge towards the middle part of the insert body along an inclined downward direction; a first bulge in a circular truncated cone shape and a second bulge in an inverted V shape are sequentially arranged in the direction from the front tool surface to the middle part of the blade body corresponding to the arc cutting edge, and the first bulge and the second bulge are in symmetrical structures along the angle bisector of the acute angle part of the blade body respectively; the first protrusion and the second protrusion respectively comprise a top surface and a side surface; the top surface of the first protrusion is higher than the position of the arc cutting edge, and the top surface of the second protrusion is higher than the top surface of the first protrusion.

The top surface of the first bulge is a plane and is parallel to the lower surface; the side surface of the first bulge is a curved surface.

The height difference between the position of the top surface of the first bulge and the position of the arc cutting edge is 0.025-0.065 mm; and along the angular bisector direction of the acute angle corner of the blade body, the minimum distance between the top surface of the first protrusion and the arc cutting edge is 0.2-1 mm.

The top surface of the second bulge is a plane and is parallel to the lower surface; the side surface of the second bulge is a curved surface.

The height difference between the top surface position of the second protrusion and the position of the arc cutting edge is 0.1-0.3 mm; the included angle between the side surface and the lower surface of the first bulge is larger than the included angle between the side surface and the lower surface of the second bulge.

The side surface of the first bulge is gently transited to the side surface of the second bulge along the angular bisector direction of the acute-angle corner of the blade body; the length of the side of the second protrusion is greater than the length of the side of the first protrusion.

The distance from the line segment cutting edge to the side of the second protrusion is greater than the distance from the line segment cutting edge to the side of the first protrusion from a direction perpendicular to the line segment cutting edge.

The inclination angle of the front tool face of the arc cutting edge relative to the lower surface is alpha, and alpha is more than or equal to 2 degrees and less than or equal to 4 degrees; the inclination angle of the front tool face of the line segment cutting edge relative to the lower surface is beta, and beta is more than or equal to 5 degrees and less than or equal to 9 degrees.

The projection of the outline of the blade body is in a diamond shape, and two corners of the four corners of the diamond shape of the blade body are acute angles.

The side is inclined plane relative to the vertical plane of the lower surface, and the side is inclined inwards gradually from top to bottom.

Compared with the prior art, the invention has the beneficial effects that:

according to the invention, as the upper surface of the blade body is adopted, the cutting edge extends towards the middle part of the blade body along the oblique downward direction to form a front tool face; a first bulge in a circular truncated cone shape and a second bulge in an inverted V shape are sequentially arranged in the direction from the front tool surface to the middle part of the blade body corresponding to the arc cutting edge, and the first bulge and the second bulge are in symmetrical structures along the angle bisector of the acute angle part of the blade body respectively; the first protrusion and the second protrusion respectively comprise a top surface and a side surface; the top surface of the first protrusion is higher than the position of the arc cutting edge, and the top surface of the second protrusion is higher than the top surface of the first protrusion. According to the invention, the specific protruding structures (namely the first protrusion and the second protrusion) are designed in the chip groove, so that the sufficient chip containing space is ensured, the sharpness of the cutter is enhanced, the effect of the cutter on chips is enhanced, the chips can be effectively controlled during small-feed small-cutting-depth machining and cutting-depth change of small parts, and the service life of the cutter and the surface quality of a workpiece are improved.

The invention is further explained in detail with the accompanying drawings and the embodiments; however, a turning insert for small parts working according to the present invention is not limited to the embodiment.

Drawings

FIG. 1 is a schematic perspective view of an embodiment of the present invention;

FIG. 2 is a top view of an embodiment of the present invention;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2;

FIG. 4 is an enlarged schematic view of section B of FIG. 3;

FIG. 5 is a sectional view taken along line C-C of FIG. 2;

fig. 6 is an enlarged schematic view of a portion D in fig. 2.

In the figure: 1. a blade body; 11. a screw lock hole; 2. an upper surface; 21. positioning a plane; 3. a lower surface; 4. a side surface; 5. a cutting edge; 51. a circular arc cutting edge; 52. a line segment cutting edge; 6. a rake face; 61. a rake face of the arc cutting edge; 62. a rake face of the line segment cutting edge; 7. a protrusion; 71. a first protrusion; 711. a top surface of the first protrusion; 712. a side of the first protrusion; 72. a second protrusion; 721. a top surface of the second protrusion; 722. the side of the second protrusion.

Detailed Description

Examples

Referring to fig. 1 to 6, a turning insert for machining a small part according to the present invention includes an insert body 1; the projection of the outline of the blade body 1 is in a polygonal shape; as shown in fig. 2, the contour projection of the insert body of the present embodiment is a diamond shape, and of the four corners of the diamond shape of the insert body, two corners are acute angles; the insert body 1 has an upper surface 2, a lower surface 3 and a side surface 4 connected between the upper and lower surfaces; the middle part of the blade body 1 is provided with a screw locking hole 11 penetrating through the upper surface and the lower surface; the insert body, in the acute corner of the insert body 1, the upper surface 2 intersects the side surface 4 to form a cutting edge 5; the cutting edge 5 comprises a circular arc cutting edge 51 corresponding to the angular point and a line segment cutting edge 52 connected with two sides of the circular arc cutting edge; in the present embodiment, the line segment cutting edges 52 are four boundaries of equal length that form the diamond-shaped upper surface 2; the arc cutting edge 51 and the line segment cutting edge 52 are both parallel to the lower surface 3, and the structure can ensure the strength of the cutting edge 5, so that the cutting edge is not easy to break in the using process; a rake surface 6 is formed on the upper surface 2 so as to extend from the cutting edge 5 to the middle of the insert body 1 in an obliquely downward direction; it should be noted that the direction toward the middle of the insert body 1 refers to the direction toward the inside of the body, and the downward direction refers to the direction from the upper surface 2 toward the lower surface 3; the middle part of the upper surface 2, namely the periphery corresponding to the screw locking hole 11 is provided with a positioning plane 21, the lower surface 3 is a plane, and the positioning plane 21 is parallel to the lower surface 3; a chip groove is formed by extending the rake face 6 to the positioning plane 21; a bulge 7 is arranged from the front tool surface 6 to the middle direction of the blade body 1 corresponding to the arc cutting edge 51, specifically, a first bulge 71 in a circular truncated cone shape and a second bulge 72 in an inverted V shape are sequentially arranged, and the first bulge 71 and the second bulge 72 are respectively in a symmetrical structure along the angular bisector of the acute angle part of the blade body; the first projection 71 and the second projection 72 include a top surface and a side surface, respectively; the highest point of the first protrusion 71 is the top surface 711 of the first protrusion 71, the top surface 711 of the first protrusion 71 is higher than the arc cutting edge 51, and the top surface 721 of the second protrusion 72 is higher than the top surface 711 of the first protrusion 71.

In this embodiment, the top surface 711 of the first protrusion 71 is a plane and parallel to the lower surface 3; the side 712 of the first protrusion 71 is a curved surface, and the side 712 of the first protrusion 71 is a curved surface extending obliquely upward toward the center of the first protrusion 71.

In the present embodiment, the height difference between the top surface position of the first protrusion 71 and the position of the arc cutting edge 51 is 0.025mm to 0.065 mm; the minimum distance between the top surface 711 of the first protrusion 71 and the circular arc cutting edge 51 is 0.2mm to 1mm along the bisector direction of the acute corner of the insert body. This minimum distance arrangement ensures that the chips are effectively processed during the cutting process.

In this embodiment, the top surface 721 of the second protrusion 72 is planar and parallel to the lower surface 3; the side surface 722 of the second protrusion 72 is a curved surface, the side surface 722 of the second protrusion 72 is a curved surface extending obliquely upward toward the center line of the second protrusion 72, and the top surface 721 of the second protrusion 72 is a plane located above the side surface 722 of the second protrusion 72.

In this embodiment, the height difference between the top surface of the second protrusion 72 and the arc cutting edge 51 is 0.1mm to 0.3 mm.

In this embodiment, as shown in fig. 4, an included angle θ 712 between the side surface 712 of the first protrusion 71 and the lower surface 3 is greater than an included angle θ 722 between the side surface 722 of the second protrusion 72 and the lower surface 3.

As shown in fig. 4, the angle θ 712 of the first side surface 712 with respect to the lower surface 3 is greater than the angle θ 722 of the second side surface 722 with respect to the lower surface 3. It should be noted that the included angles described herein are all obtained from a sectional view taken through the bisector of the circular arc cutting edge 52 and perpendicular to the plane of the lower surface 3.

In this embodiment, the side 712 of the first protrusion 71 transitions smoothly to the side 722 of the second protrusion 72 along the bisector direction of the acute corner of the insert body; the side 722 of the second projection 72 has a length greater than that of the side 712 of the first projection 71, and this structure can highly maintain the chip breaking performance with a large cutting depth.

In the present embodiment, the distance from the line segment cutting edge 52 to the side face 722 of the second protrusion 72 is greater than the distance from the line segment cutting edge 52 to the side face 712 of the first protrusion 71 in the direction perpendicular to the line segment cutting edge 52.

In the present invention, the distance from the segment cutting edge 52 to the projection 7 gradually increases as the distance from the circular arc cutting edge 51 increases, and the distance to the chip increases.

In the present embodiment, chips generated during the small-cut deep machining are effectively processed at the position of the side surface 712 of the first land 71 by the rake surface 6. As the cutting depth increases, the main location of chip disposal is gradually shifted from the side 712 of the first protrusion 71 to the side 722 of the second protrusion 72. Like this, in certain depth of cut within range, no matter be little depth of cut or big depth of cut, or the operating mode processing that changes at the depth of cut, can both properly effectively handle the smear metal for the smear metal can be stabilized curly, and the fracture is smoothly discharged.

As shown in fig. 4, in the present embodiment, the top surface 711 of the first protrusion 71 is present between the side surface 712 of the first protrusion 71 and the side surface 722 of the second protrusion 72, and the top surface 711 of the first protrusion 71 is parallel to the lower surface 3, so that the chip disposal function of protruding the side surface 722 of the second protrusion 72 can be performed under the condition of small cutting depth and large feeding, and the clogging of chips on the rake surface 6 and the protrusion 7 can be effectively reduced.

In addition, in the present embodiment, as shown in fig. 4, the side surfaces 712 of the first protrusions 71 and the side surfaces 722 of the second protrusions 72 in the protrusions 7. The side surface 712 of the first protrusion 71 starts to extend in an inner oblique upward direction at the inner position of the rake surface 6 and ends in the top surface 711 of the first protrusion 71. The side surface 722 of the second protrusion 72 starts to extend obliquely upward inwardly from the top surface 711 of the first protrusion 71 and ends at the top surface 721 of the second protrusion 72.

With the above-described structure, the curled chips can be stably controlled by the side 712 of the first protrusion 71 and the side 722 of the second protrusion 72 having a slope, which varies slowly, at the time of varying the cutting depth. In addition, in the case of small-cut-depth large-feed, the chip-disposal action of the side face 722 of the second projection 72 can be sufficiently exhibited. In a word, under the action of the structure, the excellent chip removal and breaking capacity can be displayed under wide working conditions.

In the present embodiment, the first projection 71 and the second projection 72 are each symmetrical with respect to the bisector of the circular arc cutting edge 51. Thus, the generated chips can be brought into good contact with the side surface 712 of the first land 71 and the side surface 722 of the second land 72 along the bisector of the circular arc cutting edge 51 at the small cutting depth, and the chips can be discharged stably.

With this configuration, the distance to be applied to the chips increases with the increase in the cutting depth, and the curl diameter of the chips can be adjusted, thereby stably curling the chips. In a word, under the action of the structure, the excellent chip removal and breaking capacity can be displayed under wide working conditions.

In the present embodiment, as shown in fig. 6, the rake surface 61 and the small portion rake surface 62 are provided between the circular arc cutting edge 51 and the first protrusion 71, and the rake surface 62 is provided between the line segment cutting edge 52 and the first protrusion 71 or the second protrusion 72. The inclination angle of the rake face 61 of the circular arc cutting edge 51 relative to the lower surface 3 is alpha, and alpha is more than or equal to 2 degrees and less than or equal to 4 degrees, and the strength of the circular arc cutting edge 51 can be ensured by the arrangement of the inclination angle alpha; the inclination angle of the front tool surface 62 of the line segment cutting edge 52 relative to the lower surface 3 is beta, and beta is more than or equal to 5 degrees and less than or equal to 9 degrees; the sharpness of the line segment cutting edge 52 can be ensured by providing the inclination angle β. This ensures the sharpness of the line segment cutting edge 52.

With this configuration, in a small cutting depth, the generated chips can be curled by the rake surface 61 of the first protrusion 71 first, and then stably curled by the side surface 712 of the first protrusion 71, so that the chips can be smoothly discharged.

In this embodiment, the vertical surface of the side surface 4 relative to the lower surface is an inclined surface, i.e., an included angle γ is formed, the included angle γ is an acute angle, and the side surface 4 is inclined inward gradually from top to bottom. This structure can prevent the tool from unnecessarily contacting the machined surface of the workpiece.

The invention relates to a turning blade for small part processing, which adopts the technical scheme that in the upper surface 2 of a blade body 1, a front blade surface 6 is formed by extending a cutting edge 5 towards the middle part of the blade body 1 along an inclined downward direction; a first bulge 71 in a circular truncated cone shape and a second bulge 72 in an inverted V shape are sequentially arranged from the rake surface 6 to the middle direction of the insert body 1 corresponding to the arc cutting edge 51, and the first bulge 71 and the second bulge 72 are respectively in a symmetrical structure along an angular bisector of an acute angle corner of the insert body; the first projection 71 and the second projection 72 respectively include

top surfaces

711 and 721 and

side surfaces

712 and 722; the top surface 711 of the first protrusion 71 is located higher than the circular arc cutting edge 51, and the top surface 721 of the second protrusion 72 is located higher than the top surface 711 of the first protrusion 71. According to the invention, the specific protruding structures (namely the first protrusion 71 and the second protrusion 72) are designed in the chip grooves, so that the sufficient chip containing space is ensured, the sharpness of the tool is enhanced, the effect of the chip containing space on the chip is enhanced, the chip can be effectively controlled during small-feed small-cut-depth machining and cutting-depth change of small parts, and the service life of the tool and the surface quality of a workpiece are improved. The invention can effectively reduce the blockage of the chips at the positions of the rake face 6 and the bulge 7 by the chip processing function of the side face 722 of the second bulge 72 under the working condition of small cutting depth and large feeding. In the case of small-depth cutting, the generated chips are effectively processed at the first side surface 712 of the circular truncated cone-shaped protrusion 71 by the rake surface 6. As the cutting depth increases, the main location of chip disposal is gradually shifted from the side 712 of the first protrusion 71 to the side 722 of the second protrusion 72. Like this, in certain depth of cut within range, no matter be little depth of cut or big depth of cut, or the operating mode processing that changes at the depth of cut, can both properly effectively handle the smear metal for the smear metal can be stabilized curly, and the fracture is smoothly discharged.

The foregoing is considered as illustrative of the preferred embodiments of the invention and is not to be construed as limiting the invention in any way. Although the present invention has been described with reference to the preferred embodiments, it is not intended to be limited thereto. Those skilled in the art can make many possible variations and modifications to the disclosed embodiments, or equivalent modifications, without departing from the scope of the disclosed embodiments. Therefore, any simple modification, equivalent change and modification made to the above embodiments according to the technical spirit of the present invention should fall within the protection scope of the technical scheme of the present invention, unless the technical spirit of the present invention departs from the content of the technical scheme of the present invention.

Claims

1. A turning blade for machining small parts comprises a blade body; the projection of the outline of the blade body is in a polygonal shape; the blade body having an upper surface, a lower surface and a side surface connected between the upper and lower surfaces; the middle part of the blade body is provided with a screw locking hole penetrating through the upper surface and the lower surface; at least one of the corners of the insert body is acute, and the upper surface and the side surface intersect to form a cutting edge in the acute corner of the insert body; the cutting edge comprises an arc cutting edge corresponding to the corner tip and a line segment cutting edge connected with two sides of the arc cutting edge; in the upper surface, a front tool face is formed by extending the cutting edge towards the middle part of the insert body along an inclined downward direction; the method is characterized in that: a first bulge in a circular truncated cone shape and a second bulge in an inverted V shape are sequentially arranged in the direction from the front tool surface to the middle part of the blade body corresponding to the arc cutting edge, and the first bulge and the second bulge are in symmetrical structures along the angle bisector of the acute angle part of the blade body respectively; the first protrusion and the second protrusion respectively comprise a top surface and a side surface; the top surface of the first protrusion is higher than the position of the arc cutting edge, and the top surface of the second protrusion is higher than the top surface of the first protrusion.

2. The turning insert for small part machining according to claim 1, characterized in that: the top surface of the first bulge is a plane and is parallel to the lower surface; the side surface of the first bulge is a curved surface.

3. The turning insert for small part machining according to claim 2, characterized in that: the height difference between the position of the top surface of the first bulge and the position of the arc cutting edge is 0.025-0.065 mm; and along the angular bisector direction of the acute angle corner of the blade body, the minimum distance between the top surface of the first protrusion and the arc cutting edge is 0.2-1 mm.

4. The turning insert for small part machining according to claim 2, characterized in that: the top surface of the second bulge is a plane and is parallel to the lower surface; the side surface of the second bulge is a curved surface.

5. The turning insert for small part machining according to claim 4, characterized in that: the height difference between the top surface position of the second protrusion and the position of the arc cutting edge is 0.1-0.3 mm; the included angle between the side surface and the lower surface of the first bulge is larger than the included angle between the side surface and the lower surface of the second bulge.

6. The turning insert for small part machining according to claim 5, characterized in that: the side surface of the first bulge is gently transited to the side surface of the second bulge along the angular bisector direction of the acute-angle corner of the blade body; the length of the side of the second protrusion is greater than the length of the side of the first protrusion.

7. The turning insert for small part machining according to claim 6, characterized in that: the distance from the line segment cutting edge to the side of the second protrusion is greater than the distance from the line segment cutting edge to the side of the first protrusion from a direction perpendicular to the line segment cutting edge.

8. The turning insert for small part machining according to claim 1, characterized in that: the inclination angle of the front tool face of the arc cutting edge relative to the lower surface is alpha, and alpha is more than or equal to 2 degrees and less than or equal to 4 degrees; the inclination angle of the front tool face of the line segment cutting edge relative to the lower surface is beta, and beta is more than or equal to 5 degrees and less than or equal to 9 degrees.

9. The turning insert for small part machining according to claim 1, characterized in that: the projection of the outline of the blade body is in a diamond shape, and two corners of the four corners of the diamond shape of the blade body are acute angles.

10. The turning insert for small part machining according to claim 1, characterized in that: the side is inclined plane relative to the vertical plane of the lower surface, and the side is inclined inwards gradually from top to bottom.