CN212384619U

CN212384619U - Superhard grooving tool with chip breaker groove

Info

Publication number: CN212384619U
Application number: CN201922368175.9U
Authority: CN
Inventors: 林文坤; 何耿煌; 李凌祥; 祝泉水; 赵喆; 陈潇杰; 彭仕昌; 张昌荣
Original assignee: Xiamen Golden Egret Special Alloy Co Ltd
Current assignee: Xiamen Golden Egret Special Alloy Co Ltd
Priority date: 2019-12-25
Filing date: 2019-12-25
Publication date: 2021-01-22
Anticipated expiration: 2029-12-25

Abstract

The utility model discloses a superhard grooving cutter with a chip breaker groove, which comprises a cutter body, wherein the cutter body is provided with a cutting part; the cutting part is made of superhard material and comprises a cutting edge and a chip breaker groove; the cutting edge comprises a middle V-shaped edge and two side edges; the chip breaker is generally concave and comprises a first groove at the cutting edge, a second groove at the bottom of the chip breaker and a third groove from the cutting edge to the arc inward-concave curved surface part at the rear end; the first groove is provided with an included angle with a specific size formed by bending and connecting from the middle to two sides; the second groove is lower than the blade platform; the included angle formed by bending the middle part of the third groove to the two sides is combined with the first groove to change, and the third groove is obliquely arranged and respectively and equally changed to the two sides. The utility model discloses have the wrapping cuttings, reduce the good performance of smear metal width, solved present high rigidity material grooving in-process, technical problem such as the difficult processing of smear metal makes the aspect performance such as life, machining efficiency and the smear metal of cutter handled obtain promoting comprehensively.

Description

Superhard grooving tool with chip breaker groove

Technical Field

The utility model relates to the technical field of cutters, especially, relate to a take superhard grooving cutter of chip breaker.

Background

When machining of engine accessories, gears and the like with high-hardness materials in the prior art, long and thin chips are easy to generate due to the problems of high hardness, small feeding and the like, and are wound on a cutter and a workpiece, so that the damage of a machining surface is caused and the damage of the cutter is aggravated; with the development of high speed, high efficiency, high precision and automation of mechanical manufacturing and the successive appearance and wide application of various hard materials, the surface quality of groove wall processing, the service life of the groove, the chip breaking performance and the like become main indexes for evaluating the cutting performance of the superhard cutting tool. The high-hardness grooving cutter with the chip breaking grooves enables chips to be properly processed during machining of high-hardness materials, and cutter performance is improved.

At present, the superhard cutters at home and abroad are mainly flat plates or simple groove-shaped cutters. It is not substantially used for a superhard cutter with a chip breaker and excellent chip handling capacity. In the grooving process of the superhard grooving tool in the prior art, the problems that long and wide chips generated by tool grooving are wound on a workpiece and difficult to clean the chips, the generated long and wide chips scratch a machined surface, the chip treatment effect is poor, high temperature is concentrated, and the tool is worn prematurely and the like mainly exist.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome prior art not enough, provide a take superhard grooving cutter of chip breaker, have the package and roll up the smear metal, reduce the good performance of smear metal width, solved present high rigidity material grooving in-process, technical problem such as the difficult processing of smear metal makes the aspect performance such as life, machining efficiency and the smear metal processing of cutter obtain promoting comprehensively.

The utility model provides a technical scheme that its technical problem adopted is: a superhard grooving cutter with a chip breaker groove comprises a cutter body, wherein two ends of the cutter body are provided with rotationally symmetrical cutting parts; the cutting part is made of superhard material; the cutting portion includes a cutting edge at a forward end and a chip breaker extending inwardly from the forward end; the cutting edge comprises a middle V-shaped edge and two side edges; the chip breaker is generally concave and comprises a first groove at the cutting edge, a second groove at the bottom of the chip breaker and a third groove from the cutting edge to the arc inward concave curved surface part at the rear end; the first groove is provided with an included angle with a specific size formed by bending and connecting from the middle to two sides; the second groove is lower than the blade platform; the included angle formed by bending the middle part of the third groove to two sides is combined with the first groove to change, and the third groove is obliquely arranged and is respectively changed to the two sides equally.

The chip breaker is also provided with a rear arm and a front arm which are symmetrical along an axis, the upper edge of the rear arm is provided with a third groove with the minimum width, and a second groove which is in transition with the first groove and the third groove is arranged at the position, corresponding to the first groove, on the lower side of the rear arm; the front arm and the rear arm have a distinct rising face and a convex corner at the intersection.

The angles of the cutting parts on two sides of the cross section of the first groove, which are deviated outwards and downwards from the horizontal plane, are recorded as theta₁The size range is as follows: 0.5 to 2.0 degrees.

From the first groove to the third groove, the outward downward deflection angle formed by the cutting parts on two sides of the cross section and the horizontal plane is recorded as theta₂The size of the alloy is uniformly changed from 0.5-2.0 degrees to 3.0-4.0 degrees.

The first groove is bent from the middle to two sides, the middle of the cross section of the first groove is V-shaped, the included angle of the V-shaped groove is marked as alpha, and the size range of the V-shaped groove is 130-140 degrees.

The second groove is bent from the middle to two sides, the middle of the cross section of the second groove is V-shaped, the included angle of the V-shaped groove is beta, beta is smaller than alpha, and the size range of beta is 110-125 degrees.

The third groove is bent from the middle to two sides, the middle of the cross section of the third groove is V-shaped, the included angle of the V-shaped groove is gamma, gamma is smaller than beta, and the size range of gamma is 80-100 degrees.

The chip breaker is approximately 0-shaped and has a structure with a narrow front part and a narrow middle part.

The cutter body comprises a base body made of hard alloy materials, two substrates made of hard alloy materials and two blade blocks made of superhard materials, and the cutting part is arranged in the blade blocks; the two blade blocks made of the superhard materials are respectively fixed at two ends of the base body through two substrates made of hard alloy materials.

The bottom of the base body of the cutter body is provided with a heat dissipation groove.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model adopts the cutting edge comprising the middle V-shaped edge and the two side edges; the chip breaker is generally concave and comprises a first groove at the cutting edge, a second groove at the bottom of the chip breaker and a third groove from the cutting edge to the arc inward-concave curved surface part at the rear end; the first groove is provided with an included angle with a specific size formed by bending and connecting from the middle to two sides; the second groove is lower than the blade platform; the included angle formed by bending the middle part of the third groove to two sides is combined with the first groove to change, and the third groove is obliquely arranged and is respectively changed to the two sides equally. The utility model discloses a this kind of structure utilizes the cooperation of first recess, second recess and third recess in the chip breaker, has the package and rolls up the smear metal, reduces the good performance of smear metal width, has solved present high rigidity material grooving in-process, and technical problem such as the smear metal is difficult to be handled makes the aspect performance such as life, machining efficiency and the smear metal of cutter handle promoted comprehensively.

The present invention will be described in further detail with reference to the accompanying drawings and examples; however, the superhard grooving tool with the chip breaker groove of the present invention is not limited to the embodiment.

Drawings

Fig. 1 is an exploded perspective view of an embodiment of the present invention;

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

FIG. 3(a) is a sectional view taken along line A-A in FIG. 2;

FIG. 3(B) is a sectional view taken along line B-B in FIG. 2;

fig. 3(C) is a sectional view taken along line C-C in fig. 2.

In the figure, 1, a blade body; 2. a first groove of a chip breaker; 3. a second groove of the chip breaker; 4. a third groove of the chip breaker; 5. a rear arm of the chip breaker; 6. a bottom heat sink of the blade body; 7. a cutting edge; 8. the forearm of the chip breaker; 9. a bottom of the blade body; 71. a V-shaped edge in the cutting edge; 72. an edge of the cutting edge; 10. a base of the blade body; 11. a hard alloy layer of the blade body; 12. a blade block of the blade body; alpha, a V-shaped angle in the middle of the first groove of the chip breaker; beta, a V-shaped angle in the middle of a second groove of the chip breaker; gamma, a V-shaped angle in the middle of a third groove of the chip breaker; theta 1, an included angle between an edge of the cutting edge and a horizontal line; theta 2, and the included angle between the groove edge of the chip breaker and the horizontal line.

Detailed Description

Examples

Referring to fig. 1 to 3, the superhard grooving tool with the chip breaker of the present invention comprises a tool body 1, wherein two ends of the tool body 1 are provided with rotationally symmetric cutting portions; the cutting part is made of superhard material; the cutting portion comprises a cutting edge 7 at a forward end and a chip breaker groove extending inwardly from the forward end; the cutting edge 7 comprises a V-shaped edge 71 in the middle and edge edges 72 on two sides; the chip breaker is generally concave and comprises a first groove 2 at the cutting edge, a second groove 3 at the bottom of the chip breaker and a third groove 4 from the cutting edge to the arc inward concave curved surface part at the rear end; the first groove 2 is bent and connected from the middle to two sides to form an included angle with a specific size; the second groove 3 is lower than the blade platform; the included angle formed by bending the middle part of the third groove 4 to two sides is combined with the first groove to change, and the third groove 4 is obliquely arranged and is respectively changed equally to two sides.

In this embodiment, the chip breaker is further provided with a rear arm 5 and a front arm 8 which are axially symmetrical, the upper edge of the rear arm 5 is provided with a third groove 4 with the minimum width, and a second groove 3 which is in transition with the first groove 2 and the third groove 4 is arranged at the position, corresponding to the first groove 2, on the lower side of the rear arm 5; the front arm 8 and the rear arm 5 have a distinct rising face and lobe at their intersection.

In this embodiment, as shown in fig. 3(a), the angles of the cutting portions on both sides of the cross section of the first groove 2, which are deviated outward and downward from the horizontal plane, are represented as θ₁The size range is as follows: 0.5 to 2.0 degrees.

In this embodiment, as shown in fig. 3(b), the outward downward deviation angle formed by the cutting portions on both sides of the cross section and the horizontal plane from the first groove 2 to the third groove 4 is represented as θ₂The size of the alloy is uniformly changed from 0.5-2.0 degrees to 3.0-4.0 degrees.

In this embodiment, as shown in fig. 3(a), the first groove 2 is bent from the middle to both sides, the middle of the cross section thereof is V-shaped, the included angle of the V-shaped groove is α, and the size range thereof is 130 to 140 °.

In this embodiment, as shown in fig. 3(b), the second groove 3 is bent from the middle to both sides, the middle of the cross section thereof is V-shaped, the included angle of the V-shaped groove is β, β is smaller than α, and the size range of β is 110 to 125 °.

In this embodiment, as shown in fig. 3(c), the third groove 4 is bent from the middle to both sides, the middle of the cross section thereof is V-shaped, the included angle of the V-shaped groove is γ, γ is smaller than β, and the range of γ is 80 to 100 °.

In this embodiment, the chip breaker is substantially 0-shaped, and has a structure with a narrow front and back and a wide middle.

In this embodiment, the tool body 1 includes a base 10 made of cemented carbide, two substrates 11 made of cemented carbide, and two insert blocks 12 made of superhard material, and the cutting portion is provided in the insert blocks 12; the two blade blocks 12 made of superhard materials are respectively fixed at two ends of the base body 10 through two substrates 11 made of hard alloy materials; wherein the superhard material is Polycrystalline Cubic Boron Nitride (PCBN) (polycrystalline Cubic Boron nitride).

In this embodiment, the bottom of the base 10 of the tool body 1 is provided with a heat sink 6.

In this embodiment, the tool body 1 is divided into three parts: a cemented carbide base body 10, a cemented carbide substrate 11, and an ultra-hard layer 12. The cutter is a body which is axisymmetric along the left surface, the right surface, the front surface and the rear surface respectively, two V-shaped curve cutting edges 7 are arranged, the outmost part of each cutting edge is a first groove 2, and the middle part of each groove is bent towards two sides to form a specific included angle, so that in the initial grooving process, firstly, chips are wrapped by the first grooves 2, and particularly, spiral spring-shaped chips which are narrower than the width of the cutter and reflect the first grooves 2 and have wavy waves on two sides are formed aiming at thin and soft non-breakable chips generated in small feeding, thereby effectively improving the rigidity of the chips in the grooving process and being beneficial to chip breaking; but also avoids the friction between the cutting chips and the processed surface, reduces the cutting force and improves the surface quality.

The chips pass through the front cutter face, and have more stable forms under the guide action of friction force and the front arm 8, so that a good centering effect is achieved; when the cutting fluid passes through the second groove 3 and reaches the third groove 4, the groove 8 becomes narrow, the direction of chips tends to narrow, the curling radius of the chips is reduced under the action of the third groove 4, the chips are broken easily, the main cutting force generated in cutting can be dispersed, and the cutting load is reduced.

The V-shaped curve cutting edge 7 is matched with the first groove 2, the tool tips at two ends are firstly cut during cutting, then the contact of the whole cutting edge is gradually increased, the impact effect of the cutting tool on the cutting tool in the cutting-in instant cutting force can be effectively reduced, the grooving processing stability is improved, and the tool tip is prevented from being broken.

The rear arm 5 which is axisymmetric is arranged at the third groove 4 of the chip breaker, so that the strength of a grooving tool can be effectively improved, and meanwhile, when the chip is machined, the curling radius of the chip can be effectively reduced after the chip passes through the rear arm 5, so that the chip breaking performance is improved, the contact area of the tool with cooling liquid and air is increased by the rear arm 5, a large amount of cutting heat is taken away by the chip and a cooling medium, and the cutting temperature of the tool is reduced.

The bottom surface 9 of the cutter body 1 is provided with the bottom heat dissipation groove 6, the design can not only avoid the deformation problem of the cutter, but also reduce the contact area between the cutter and the cutter body, and simultaneously can guide a cooling medium into the periphery of the bottom of the cutter to play a role in fully cooling the cutter.

The utility model relates to a superhard grooving tool with chip breaker groove, which adopts a cutting edge 7 comprising a V-shaped edge 71 in the middle and edge edges 72 at two sides; the chip breaker is generally concave and comprises a first groove 2 at the cutting edge, a second groove 3 at the bottom of the chip breaker and a third groove 4 from the cutting edge to the arc inward concave curved surface part at the rear end; the first groove 2 is bent and connected from the middle to two sides to form an included angle with a specific size; the second groove 3 is lower than the blade platform; the included angle formed by bending the middle part of the third groove 4 to two sides is changed in a combined manner, and the third groove 4 is obliquely arranged and is respectively changed equally to two sides. The utility model discloses a this kind of structure utilizes the cooperation of first recess, second recess and third recess in the chip breaker, has the package and rolls up the smear metal, reduces the good performance of smear metal width, has solved present high rigidity material grooving in-process, and technical problem such as the smear metal is difficult to be handled makes the aspect performance such as life, machining efficiency and the smear metal of cutter handle promoted comprehensively. The first groove 2 of the grooving cutter can effectively treat chips, the contact area of a cutting edge and a workpiece is gradually increased, the impact effect of the cutting force of the cutter on the cutter at the cutting-in moment can be effectively relieved, and the cutting force in the machining process can be reduced, so that the stability of the cutter is improved, and the mechanical load borne by the cutter is effectively reduced; chip breaking and removal performance and smoothness of the grooving process. The groove-shaped structure of the superhard grooving cutter can effectively improve the guiding and centering effects on cuttings, and spring cuttings which are narrower than the cutter width and have wavy undulations on two sides and are remapped in the groove are formed, so that the rigidity of the cuttings in the grooving process can be effectively improved, and the cuttings can be broken; but also avoids the friction between the cutting chips and the machined surface and improves the surface quality.

The foregoing is illustrative of the preferred embodiment of the present 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 limit the present invention. The technical solutions disclosed above can be used by those skilled in the art to make many possible variations and modifications, or to modify equivalent embodiments, without departing from the scope of the present invention. Therefore, any simple modification, equivalent change and modification made to the above embodiments by the technical entity of the present invention should fall within the protection scope of the technical solution of the present invention.

Claims

1. A superhard grooving cutter with a chip breaker groove comprises a cutter body, wherein two ends of the cutter body are provided with rotationally symmetrical cutting parts; the cutting part is made of superhard material; the cutting portion includes a cutting edge at a forward end and a chip breaker extending inwardly from the forward end; the method is characterized in that: the cutting edge comprises a middle V-shaped edge and two side edges; the chip breaker is generally concave and comprises a first groove at the cutting edge, a second groove at the bottom of the chip breaker and a third groove from the cutting edge to the arc inward concave curved surface part at the rear end; the first groove is bent and connected from the middle to two sides to form an included angle; the second groove is lower than the blade platform; the included angle formed by bending the middle part of the third groove to two sides is combined with the first groove to change, and the third groove is obliquely arranged and is respectively changed to the two sides equally.

2. A flute-breaker superhard grooving tool as claimed in claim 1 wherein: the chip breaker is also provided with a rear arm and a front arm which are symmetrical along an axis, the upper edge of the rear arm is provided with a third groove with the minimum width, and a second groove which is in transition with the first groove and the third groove is arranged at the position, corresponding to the first groove, on the lower side of the rear arm; the front arm and the rear arm have a distinct rising face and a convex corner at the intersection.

3. A chip breaker superhard grooving tool as claimed in claim 1 or 2, whereinIs characterized in that: the angles of the cutting parts on two sides of the cross section of the first groove, which are deviated outwards and downwards from the horizontal plane, are recorded as theta₁The size range is as follows: 0.5 to 2.0 degrees.

4. A flute-breaker superhard grooving tool as claimed in claim 3 wherein: from the first groove to the third groove, the outward downward deflection angle formed by the cutting parts on two sides of the cross section and the horizontal plane is recorded as theta₂The size of the alloy is uniformly changed from 0.5-2.0 degrees to 3.0-4.0 degrees.

5. A flute-breaker superhard grooving tool as claimed in claim 3 wherein: the first groove is bent from the middle to two sides, the middle of the cross section of the first groove is V-shaped, the included angle of the V-shaped groove is marked as alpha, and the size range of the V-shaped groove is 130-140 degrees.

6. A flute-breaker superhard grooving tool as claimed in claim 5, wherein: the second groove is bent from the middle to two sides, the middle of the cross section of the second groove is V-shaped, the included angle of the V-shaped groove is beta, beta is smaller than alpha, and the size range of beta is 110-125 degrees.

7. A flute-breaker superhard grooving tool as claimed in claim 6, wherein: the third groove is bent from the middle to two sides, the middle of the cross section of the third groove is V-shaped, the included angle of the V-shaped groove is gamma, gamma is smaller than beta, and the size range of gamma is 80-100 degrees.

8. A flute-breaker superhard grooving tool as claimed in claim 2 wherein: the chip breaker is approximately 0-shaped and has a structure with a narrow front part and a narrow middle part.

9. A chip breaker superhard grooving tool as claimed in claim 1 or claim 2, wherein: the cutter body comprises a base body made of hard alloy materials, two substrates made of hard alloy materials and two blade blocks made of superhard materials, and the cutting part is arranged in the blade blocks; the two blade blocks made of the superhard materials are respectively fixed at two ends of the base body through two substrates made of hard alloy materials.

10. A flute-breaker superhard grooving tool as claimed in claim 9 wherein: the bottom of the base body of the cutter body is provided with a heat dissipation groove.