CN215090908U - A finish milling cutter for stellite alloy processing - Google Patents

Abstract

The utility model provides a finish milling cutter for processing department is too upright alloy, it makes when processing department is too upright alloy, and cutter cutting vibration is little, the long-term steady operation of blade, improves work piece surface finish, promotes cutting efficiency and increase of service life. The cutting tool comprises a cylindrical tool handle and a cutting tool body, wherein the cylindrical tool handle is used for being clamped and connected with a machine tool, and the cutting tool body and the cylindrical tool handle are integrally formed; the cutting tool body is provided with a plurality of spiral chip grooves, and the chip grooves and the solid part of the tool body are intersected to form a plurality of cutting edges and blade backs; the cutting edge comprises a cutting end edge, a cutting peripheral edge and a tool nose chamfer used for connecting the cutting end edge and the cutting peripheral edge, and a blade back auxiliary groove is arranged on the blade back; the cutting edges are distributed in an unequal circumferential distribution relative to the center of the front end face of the cutting cutter body in the radial direction, included angles and angles between every two adjacent cutting edges are different, the angle difference is 5-10 degrees, and the groove shape of the end section of the chip groove is formed by splicing multiple sections of circular arcs in a tangent mode to form a continuous inner groove.

Description

A finish milling cutter for stellite alloy processing

Technical Field

The utility model relates to a technical field of milling cutter structure specifically is a finish milling cutter that is used for department tai li alloy processing.

Background

Stellite alloys, also known as cobalt-chromium-tungsten (molybdenum) alloys orCobalt-based alloyThe material is a difficult-to-process material with high hardness, high toughness and low heat dissipation. The stellite alloy has high red hardness (the hardness is as high as HRC50), good thermal fatigue resistance, thermal corrosion resistance and abrasion resistance, and is widely applied to the fields of aerospace, automobile manufacturing, ship engineering, national defense war industry and the like.

The chemical components of the stellite mainly comprise: co (60%), Cr (28% -32%), W (3.5% -5.5%), C (0.9% -1.4%) and a small amount of Fe, Mn, Ni, Si and other elements. Wherein, because the melting point of the W, Cr, Si and other element components in the alloy structure is high, the high-temperature strength of the material is good, so that the cutting temperature which the cutter needs to bear during cutting is high, and the cutter point is easy to generate plastic deformation abrasion; and because the affinity between elements such as W, Co, C and the like in the alloy structure and the structure elements of the cutter material is strong, the cutter is easy to generate serious cutter sticking phenomenon in the cutting process of the cutter, and the accumulated edge is formed, thereby influencing the surface quality of workpiece processing.

Meanwhile, in the cutting process, the temperature of a contact area between the cutter and chips is high (generally more than 800 ℃), and the temperature of an edge in contact with air is low, so that the transition area of the edge is easy to generate heat cracks and grooves under the action of cutting force, namely boundary abrasion is generated. In addition, due to the manufacturing process and material properties of stellite alloy, the defects of looseness, gaps, microcracks, inclusion and the like often occur in the alloy structure, and a large number of hard particles exist, so that the impact vibration is large when the cutter is used for cutting under the action of mechanical abrasion, and the blade is easy to break and crack.

Therefore, an end mill is needed to be designed to be suitable for finish machining of stellite, solve the problems of large cutting vibration of the cutter, easy tipping and abrasion of the cutting edge and the like, and improve the surface smoothness of the workpiece, the cutting efficiency and the service life of the cutter.

Disclosure of Invention

To the problem, the utility model provides a finish milling cutter for processing of department tai li alloy, it makes when processing department tai li alloy, and cutter cutting vibration is little, the long-term steady operation of blade, improves work piece surface finish, promotes cutting efficiency and increase of service life.

A finish milling cutter for stellite processing, characterized by: the cutting tool comprises a cylindrical tool handle and a cutting tool body, wherein the cylindrical tool handle is used for being clamped and connected with a machine tool, and the cutting tool body and the cylindrical tool handle are integrally formed; the cutting tool body is provided with a plurality of spiral chip grooves, and the chip grooves and the solid part of the tool body are intersected to form a plurality of cutting edges and blade backs; the cutting edge comprises a cutting end edge, a cutting peripheral edge and a tool nose chamfer used for connecting the cutting end edge and the cutting peripheral edge, and a blade back auxiliary groove is arranged on the blade back; the cutting edges are distributed in an unequal circumferential distribution relative to the center of the front end face of the cutting cutter body in the radial direction, included angles and angles between every two adjacent cutting edges are different, the angle difference is 5-10 degrees, and the groove shape of the end section of the chip groove is formed by splicing multiple sections of circular arcs in a tangent mode to form a continuous inner groove.

It is further characterized in that:

diameter d of the cylindrical shank₁Is greater than or equal to the diameter d of the cutting tool body₂；

Diameter d of the cutting blade body ₂8 mm-14 mm, the length of the cutting edge of the cutting knife body is the diameter d₂1.5-3 times of the total weight of the composition;

core thickness d of the cutting blade body_oIs a diameter d₂0.65-0.7 times of;

the number of the cutting edges of the cutting knife body is N, wherein N is a natural number which is more than or equal to 3;

preferably, the value of N is 5;

a peripheral edge rake angle gamma of the cutting blade body_oIs 6 degrees to 8 degrees;

the angle of the helical angle beta of the cutter is 38-45 degrees;

the end edge shape of the cutting knife body is a structure that one edge passes through the center;

the end edge reentrant angle of the cutting blade body is 1.5 degrees;

the rear cutter face of the cutting peripheral edge is in the form of a conical rear cutter face;

peripheral edge relief angle alpha of the cutting tool body_o10 to 14 degrees;

first relief angle alpha of the cutting end edge₁Is 8 to 12 degrees and a second relief angle alpha₂Is 20 degrees to 22 degrees;

the chip grooves are formed in the cutting end edges of the opposite chip grooves and comprise groove bottom surfaces and tool nose platforms, the tool nose platforms are formed by the intersection of the tool nose surfaces and the cutting end edges, and the tool nose platforms are used for adjusting the size of the front angle of the cutting edges of the cutting end edges and the strength of the cutting edges so as to improve the cutting performance of the milling cutter;

the blade back is provided with a corresponding blade back auxiliary groove which is used for adjusting the width of the blade back and the space of the cutter groove for containing chips;

the coating of the cutting tool adopts titanium aluminum nitride;

and the cutter adopts passivation treatment before coating.

After the utility model is adopted, the chip groove of the cutter adopts a spiral groove structure, the groove shape is formed by tangency of a plurality of sections of circular arcs, the groove surface is connected with smooth transition, simultaneously, the rigidity and the chip removal performance are considered, and the cutter durability and the cutting efficiency are improved; the milling cutter cutting main edge adopts an unequal design, and each cutting edge generates different cutting frequencies during cutting, so that resonance between a cutter, a machine tool and a workpiece is effectively prevented, the cutter is prevented from bending and breaking due to cutting vibration, and the cutting machining precision and the surface quality are improved; when stellite alloy is processed, the cutting vibration of the cutter is small, the cutting edge stably runs for a long time, the surface finish of a workpiece is improved, the cutting efficiency is improved, and the service life is prolonged.

Drawings

Fig. 1 is a schematic front view structure diagram of the present invention;

fig. 2 is a schematic sectional view of a chip discharge groove according to the present invention;

fig. 3 is a schematic perspective view of a peripheral edge of the cutting blade body of the present invention;

fig. 4 is a schematic perspective view of an end blade of the cutting blade body of the present invention;

fig. 5 is a schematic top view of an end blade of the cutting blade body of the present invention;

fig. 6 is a schematic view of a partial sectional structure of the peripheral edge of the cutting blade of the present invention.

Detailed Description

A finish milling cutter for stellite machining, see fig. 1-6: the cutting tool comprises a cylindrical tool handle 1 and a cutting tool body 2, wherein the cylindrical tool handle 1 is used for being clamped and connected with a machine tool, and the cutting tool body 2 and the cylindrical tool handle 1 are integrally formed; the cutting tool body 2 is provided with a plurality of spiral chip grooves 3, and the chip grooves 3 are intersected with the solid part of the tool body to form a plurality of cutting edges 4 and an edge back 5; the cutting edge 4 comprises a cutting end edge 401, a cutting peripheral edge 402 and a tool nose chamfer 403 for connecting the cutting end edge 401 and the cutting peripheral edge 402, and the blade back 5 is provided with a blade back auxiliary groove; the cutting edges 4 are distributed in an unequal circumferential distribution in the radial direction relative to the center of the front end face of the cutting cutter body 2, included angles and angles between every two adjacent cutting edges 4 are different, the angle difference is 5-10 degrees, and the end section groove type of the chip groove 3 is formed by splicing multiple sections of circular arcs in a tangent mode to form a continuous inner groove.

Diameter d of the cylindrical shank 1₁Is greater than or equal to the diameter d of the cutting insert body 2₂；

Diameter d of the cutting insert 2₂8 mm-14 mm, the length of the cutting edge l of the cutting blade body 2 is the diameter d₂1.5 to 3 times of the total weight of the composition;

core thickness d of the cutting insert body 2_oIs a diameter d₂0.65-0.7 times of;

the number of the cutting edges 4 of the cutting cutter body 2 is N, wherein N is a natural number which is more than or equal to 3;

cutting peripheral edge 402 rake angle γ of cutting insert body 2_oIs 6 degrees to 8 degrees;

the angle of the helical angle beta of the cutter is 38-45 degrees;

the cutting edge shape of the cutting end of the cutting cutter body 2 is a structure that one edge passes through the center;

the end edge reentrant angle of the cutting blade body 2 is 1.5 degrees;

the flank face of the cutting peripheral edge 402 is in the form of a conical flank face;

cutting peripheral edge 402 relief angle alpha of cutting tool body 2_oIs 10 DEG to14°；

First relief angle alpha of cutting end edge 401₁Is 8 to 12 degrees and a second relief angle alpha₂Is 20 degrees to 22 degrees;

the coating of the cutting tool adopts titanium aluminum nitride; and the cutter adopts passivation treatment before coating.

In specific implementation, see fig. 1-6: diameter d of the cylindrical shank 1₁Is greater than or equal to the diameter d of the cutting tool body 2₂Minimum even value of (d), diameter d of the cutting insert body 2₂8 mm-14 mm; the rigidity of a milling cutter is inversely proportional to the edge length (overhang length), and the shorter the edge length of the cutter, the more rigid the cutter body, and the better the cutting performance, so the edge length l of the cutting cutter body is generally defined as the diameter d₂1.5-3 times of the total weight of the powder.

The number of cutting edges is one of the important factors affecting the cutting performance of the milling cutter. Generally, the smaller the number of blades is, the larger the chip containing space is, the smoother the chip removal by cutting is, but the area of the cross section of the end of the cutter is relatively smaller, the rigidity of the cutter is low, and the cutter body is easy to bend during cutting; on the contrary, the number of cutting edges increases, the cross-sectional area of the end of the cutter increases, the rigidity of the cutter body increases, but the space of the chip pocket becomes smaller, the chip holding capacity decreases, and the chip is easily clogged. In the specific embodiment, as shown in fig. 2, 5 spiral flutes 3 are arranged on the cutting tool body, the spiral flutes of the cutting tool adopt a forming groove structure, and the groove shape of the spiral flutes is formed by tangentially splicing multiple sections of the groove shape to form a continuous inner groove (as shown in fig. 6, wherein R is₁≠R₂≠R₃≠R₄) The bottom surface of the groove is in smooth transition, and simultaneously, the rigidity and the chip removal performance are considered, so that the durability and the cutting efficiency of the cutter are improved; core thickness d of cutting tool body_oIs a diameter d₂0.65 to 0.7 times of the amount of the active ingredient.

In a specific embodiment, the chip discharge groove 3 and the solid part of the cutter body intersect to form 5 cutting edges 4 and a back 5, the cutting edges 4 comprise a cutting end edge 401, a cutting peripheral edge 402 and a cutter point chamfer 403 for connecting the cutting end edge 401 and the cutting peripheral edge 402, and the cutter point chamfer 403 can effectively improve the strength of the cutter point and eliminate or avoid the occurrence of cutter point tipping or plastic deformation abrasion; the chip groove 3 is provided with a chip groove 6 at the cutting end edge 401, the chip groove 6 comprises a groove bottom surface 601 and a chip surface 602, and the chip surface 602 intersects with the cutting end edge 401 to form a chip platform 603 for adjusting the size of the front angle of the cutting edge of the cutting end edge 401 and the strength of the cutting edge to improve the cutting performance of the milling cutter. The blade back 5 is provided with a blade back auxiliary groove 501 ground by a flat-bottom grinding wheel, and the purpose of the blade back auxiliary groove is to adjust the width of the blade back and the chip containing space of a cutter groove.

In the specific embodiment, the 5 cutting edges 4 are distributed in an unequal circumferential distribution in the radial direction relative to the center of the front end surface of the cutting cutter body, namely the included angles between every two adjacent cutting edges are different, and the angle difference is 5-10 degrees; each cutting edge 4 is arranged in order of the division angle theta of the first cutting edge 4₁Is 72 DEG, and the division angle theta of the second cutting edge 4₂Is 77 DEG, the division angle theta of the third cutting edge 4₃Is 67 DEG, and the division angle theta of the fourth cutting edge 4₄Is 77 DEG, the division angle theta of the fifth cutting edge 4₅Is 67 deg.. The cutting edges of the multi-edge milling cutter adopt an unequal design, and each cutting edge generates different cutting frequencies during cutting, so that resonance between a cutter, a machine tool and a workpiece is effectively prevented, the cutter is prevented from bending and breaking due to cutting vibration, and the cutting machining precision and the surface quality are improved.

The rake face 7 has a rake angle γ in contact with the workpiece to be machined_oAnterior angle gamma_oThe size of (a) influences the shape of the chip and the strength of the cutting edge of the tool, the rake angle gamma_oThe larger the cutting edge, the sharper the cutting edge is, but the strength of the cutting edge is slightly reduced; while using a smaller rake angle gamma_oThe contact length between the chips and the rake face 7 can be increased, the stress at the edge and the cutting temperature can be reduced, the durability of the cutting tool can be improved, and the peripheral edge rake angle gamma of the cutting tool body 2 can be increased_oIs 6 degrees to 8 degrees; meanwhile, in order to improve the stability during milling and increase the actual working rake angle, the helix angle of the cutter can be properly increased, and the angle beta of the helix angle of the cutter is set to be 38-45 degrees.

In order to prevent the machined surface of the workpiece material from elastic-plastic deformation, the flank of the cutting peripheral edge is in the form of a tapered flank 8 to increase the clearance between the peripheral edge flank of the tool and the workpiece, and the peripheral edge relief angle α of the cutting tool body 2_o10 to 14 degrees; meanwhile, in order to simplify the tool grinding process, ensure that the surface of the milled workpiece has no protrusion and prevent the end face of the milling cutter from colliding with the bottom surface of the workpiece, the end edge of the cutting tool body 2 is in the shape of oneThe edge is over-center, and the concave angle delta of the end edge of the cutting edge part 2 is set to be 1.5 degrees; first relief angle alpha of the end edge of the cutting blade body 2₁Is 8 to 12 degrees and a second relief angle alpha₂Is 20-22 degrees.

In the grinding process of the milling cutter, in order to improve the surface smoothness of the cutter and reduce the frictional resistance of the cutter during cutting and chip removal, fine grinding wheels are adopted to carry out fine polishing treatment on the front cutter face and the rear cutter face of the cutting peripheral edge and the first rear cutter face of the cutting end edge. However, after the tool is finely ground and polished by the fine grinding wheel, microscopic gaps (i.e. tiny tipping and saw cuts) with different degrees still exist on the cutting edge. Therefore, before the cutter coating, the cutting edge needs to be subjected to round angle passivation through quartz sand blasting treatment, so that the cutting edge is enabled to become smooth and flat, and the defect of edge breakage is reduced. Meanwhile, the groove of the cutter is uniformly polished, the surface quality of the groove is improved, and the adhesive force of the cutter coating is enhanced, so that the smoothness of the surface of a workpiece machined by the cutter is improved.

After the cutter is ground and prepared, a titanium aluminum nitride (AlTiN) coating is selected, and the surface of the cutter is subjected to coating treatment in a Physical Vapor Deposition (PVD) mode. The AlTiN coating has good chemical stability, high hot hardness, strong adhesive force, small friction coefficient and high wear resistance; meanwhile, because the Al concentration in the film layer is higher, a layer of extremely thin amorphous Al can be generated on the surface of the cutter during cutting processing₂O₃And a hard inert protective film is formed to play a role of a thermal barrier, so that the high-temperature oxidation resistance of the surface of the cutter is effectively improved.

The beneficial effects are as follows: the chip removal groove of the cutter adopts a spiral groove structure, the groove shape of the chip removal groove is formed by tangency of a plurality of sections of circular arcs, the groove surface is connected and smoothly transited, meanwhile, the rigidity and the chip removal performance are considered, and the durability and the cutting efficiency of the cutter are improved; the milling cutter cutting main edge adopts an unequal design, and each cutting edge generates different cutting frequencies during cutting, so that resonance between a cutter, a machine tool and a workpiece is effectively prevented, the cutter is prevented from bending and breaking due to cutting vibration, and the cutting machining precision and the surface quality are improved; when stellite alloy is processed, the cutting vibration of the cutter is small, the cutting edge stably runs for a long time, the surface finish of a workpiece is improved, the cutting efficiency is improved, and the service life is prolonged; the design of the rear cutter face of the cone increases the clearance between the rear cutter face of the peripheral edge of the cutter and the workpiece, and avoids the abrasion of the cutter caused by the elastic-plastic deformation of the material; the cutter passivation treatment effectively eliminates the microscopic defects of the cutting edge and improves the strength of the cutting edge while ensuring the sharpness of the cutting edge of the cutter; the surface coating of the cutter enables the cutter to obtain excellent comprehensive mechanical properties, thereby effectively prolonging the service life of the cutter and improving the cutting efficiency.

Most of parts prepared from stellite are cast forging parts or powder metallurgy parts, and conventional milling cutters are easy to collapse and wear, so that the service life of the cutters is seriously insufficient. Through the specific case of this patent milling cutter and ordinary milling cutter of contrast, through experimental verification, as shown in table 1, the cutter life-span of five-blade unequal end milling cutter is 4 times of ordinary four-blade end milling cutter, has fully explained rationality and reliability that this patent finish milling cutter designed, can effectively improve department tai li alloy finish milling machining efficiency to extension cutter life.

TABLE 1

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (10)

1. A finish milling cutter for stellite processing, characterized by: the cutting tool comprises a cylindrical tool handle and a cutting tool body, wherein the cylindrical tool handle is used for being clamped and connected with a machine tool, and the cutting tool body and the cylindrical tool handle are integrally formed; the cutting tool body is provided with a plurality of spiral chip grooves, and the chip grooves and the solid part of the tool body are intersected to form a plurality of cutting edges and blade backs; the cutting edge comprises a cutting end edge, a cutting peripheral edge and a tool nose chamfer used for connecting the cutting end edge and the cutting peripheral edge, and a blade back auxiliary groove is arranged on the blade back; the cutting edges are distributed in an unequal circumferential distribution relative to the center of the front end face of the cutting cutter body in the radial direction, included angles and angles between every two adjacent cutting edges are different, the angle difference is 5-10 degrees, and the groove shape of the end section of the chip groove is formed by splicing multiple sections of circular arcs in a tangent mode to form a continuous inner groove.

2. A finish milling cutter for stellite machining according to claim 1, wherein: the number of the cutting edges of the cutting knife body is N, wherein N is a natural number which is more than or equal to 3.

3. A finish milling cutter for stellite machining according to claim 1, wherein: a peripheral edge rake angle gamma of the cutting blade body_oIs 6 to 8 degrees.

4. A finish milling cutter for stellite machining according to claim 1, wherein: the angle beta of the helical angle of the cutter is 38-45 degrees.

5. A finish milling cutter for stellite machining according to claim 1, wherein: the end edge shape of the cutting knife body is a structure that one edge passes through the center.

6. A finish milling cutter for stellite processing as set forth in claim 1, wherein the finish milling cutter is a cylindrical cutterCharacterized in that: the end edge reentrant angle of the cutting blade body is 1.5 degrees; peripheral edge relief angle alpha of the cutting tool body_oIs 10-14 degrees.

7. A finish milling cutter for stellite machining according to claim 1, wherein: the rear tool face of the cutting peripheral edge is in the form of a conical rear tool face.

8. A finish milling cutter for stellite machining according to claim 1, wherein: first relief angle alpha of the cutting end edge₁Is 8 to 12 degrees and a second relief angle alpha₂Is 20-22 degrees.

9. A finish milling cutter for stellite machining according to claim 1, wherein: the chip groove is to one cutting end sword department is equipped with the chip groove, the chip groove contains tank bottom surface, rake face, the rake face with the cutting end sword is crossing to form the knife tip platform, the knife tip platform is used for adjusting the size and the blade intensity of the blade anterior angle of cutting end sword.

10. A finish milling cutter for stellite machining according to claim 1, wherein: the blade back is provided with a corresponding blade back auxiliary groove which is used for adjusting the width of the blade back and the space of the cutter groove for containing chips.

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