CN105149627A - Cylindrical turning bionic cutter - Google Patents
Cylindrical turning bionic cutter Download PDFInfo
- Publication number
- CN105149627A CN105149627A CN201510680544.1A CN201510680544A CN105149627A CN 105149627 A CN105149627 A CN 105149627A CN 201510680544 A CN201510680544 A CN 201510680544A CN 105149627 A CN105149627 A CN 105149627A
- Authority
- CN
- China
- Prior art keywords
- beaver
- face
- cutter
- front tooth
- cutting edge
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Pending
Links
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23B—TURNING; BORING
- B23B27/00—Tools for turning or boring machines; Tools of a similar kind in general; Accessories therefor
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23B—TURNING; BORING
- B23B27/00—Tools for turning or boring machines; Tools of a similar kind in general; Accessories therefor
- B23B27/005—Geometry of the chip-forming or the clearance planes, e.g. tool angles
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F30/00—Computer-aided design [CAD]
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F30/00—Computer-aided design [CAD]
- G06F30/10—Geometric CAD
- G06F30/13—Architectural design, e.g. computer-aided architectural design [CAAD] related to design of buildings, bridges, landscapes, production plants or roads
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23B—TURNING; BORING
- B23B2200/00—Details of cutting inserts
- B23B2200/04—Overall shape
- B23B2200/0423—Irregular
Abstract
The invention discloses a cylindrical turning bionic cutter. The bionic cutter is characterized in that a cutter head part of the bionic cutter is in a beaver incisor bionic shape. According to the bionic cutter, the cutting edge straight line design and the rear cutter face plane type design of a traditional cutter are changed, in the using process, the smallest cutting resistance can be obtained, and the service life is long.
Description
The application is application number is 2013104888826, and the applying date is on October 18th, 2013, and denomination of invention is the bionical cutter of a kind of turning and method for designing thereof, and application people is the divisional application of the application for a patent for invention of University of Anhui.
Technical field
The present invention relates to the bionical cutter of a kind of turning and method for designing, is more particularly bionical cutter and the method for designing thereof of imitative beaver front tooth shape characteristic.
Background technology
Carrying out in cutting process to various workpiece material, optimizing tool geometry, reducing and be cut the wearing and tearing of material to cutter, reducing cutting resistance, improving stock-removing efficiency, increasing cutting-tool's used life, reducing production cost, is the problem that people extremely pay close attention to.
Modern bionics Study shows, the evolution that many animal vias are excessively long-term, the positions such as its tooth, pawl toe and body surface progressively define special geometry, there is excellent biomechanical function, the jaw ability of stinging being embodied in animal teeth is stronger, and the life-span of tooth is general also longer, therefore, according to bionic principle, tool geometrical parameter is optimized to improve cutting-tool's used life and there is positive meaning.At present, the cutting edge curve of conventional tool is mostly linear pattern, and knife face is also plane thereafter, and the cutting edge shape of cutter affects the stock-removing efficiency of cutter, and rear knife face shape is also to quality and the cutting-tool's used life important of machined surface.
Summary of the invention:
The present invention is stock-removing efficiency for improving cutter further and service life, provides the bionical cutter of a kind of turning and method for designing thereof.By extracting bionical object beaver front tooth cutting edge curve, and carry out matching and obtain cutting edge Fitting curve equation, fit equation is applied to the cutting edge design of bionical cutter; By extracting the longitudinal indicatrix of bionical object beaver front tooth and transverse features curve, matching is carried out respectively to it and obtains longitudinal indicatrix fit equation and transverse features Fitting curve equation, longitudinal indicatrix fit equation and transverse features Fitting curve equation are applied to the knife face design of bionical cutter.
The present invention is that technical solution problem adopts following technical scheme:
The bionical shape of the design feature of the bionical cutter of turning of the present invention to be the tool bit part of described bionical cutter be beaver front tooth.
The part of the cutter head of the bionical cutter of turning of the present invention has rake face, main rear knife face and minor flank, and be in described rake face and main after main cutting edge between knife face, be in front cutting edge between described rake face and minor flank, described rake face and main after the intersection point that jointly formed between knife face and minor flank be point of a knife point; Be characterized in:
The curve shape of described main cutting edge and front cutting edge characterizes by formula (1):
The main cutting edge of described bionical cutter and front cutting edge are formed projection on cutter basal plane Pr face, and define X on cutter basal plane Pr face
1o
1y
1coordinate system, described X
1o
1y
1coordinate system is with the starting point of main cutting edge in described projection for initial point, with the direction of feed V of bionical cutter
fto being X-axis, with in bionical cutter basal plane Pr face perpendicular to direction of feed V
fto Tool in Cutting depth direction be Y direction; Then in formula (1):
X
1it is the coordinate value of the X-axis that main cutting edge and front cutting edge project on cutter basal plane Pr face;
Y
1it is the coordinate value of the Y-axis that main cutting edge and front cutting edge project on cutter basal plane Pr face;
After the master of described bionical cutter, the Vertical Curve of knife face and minor flank characterizes by formula (2):
The longitudinal profile line that after the Vertical Curve of knife face and minor flank refers to described master after the master of described bionical cutter, knife face and minor flank are formed in cutter orthogonal plane Po face; Cutter orthogonal plane Po face defines X
2o
2y
2coordinate system, described X
2o
2y
2coordinate system is with the intersection point in main cutting edge, front cutting edge and orthogonal plane Po face for initial point, in orthogonal plane Po face with the cutting speed Vc of cutter to opposite direction for X
2direction of principal axis, with the direction perpendicular to cutting speed Vc for Y
2direction of principal axis; Then in formula (2):
X
2lead the X that on rear knife face and minor flank, longitudinal profile line projects on orthogonal plane Po face
2axial coordinate value;
Y
2lead the Y that on rear knife face and minor flank, longitudinal profile line projects on orthogonal plane Po face
2axial coordinate value;
After the master of described bionical cutter, the horizontal curve of knife face and minor flank characterizes by formula (3):
After after the master of described bionical cutter, the horizontal curve of knife face and minor flank refers to described master, knife face and minor flank are being parallel to cutter basal plane Pr face and the horizontal section line formed in horizontal section by point of a knife point; Described horizontal section defines X
3o
3y
3coordinate system, described X
3o
3y
3coordinate system is with the intersection point of point of a knife point and horizontal section for initial point, with the direction of feed V of cutter
fto being X-axis, with in cutter basal plane Pr face perpendicular to direction of feed V
fto the cutting depth direction of cutter be Y direction; Then in formula (3):
X
3lead the X that on rear knife face and minor flank, horizontal section line projects on horizontal section
3axial coordinate value;
Y
3lead the Y that on rear knife face and minor flank, horizontal section line projects on horizontal section
3axial coordinate value.
The present invention is the feature of the method for the bionical shape obtaining beaver front tooth is carry out as follows:
Step one, extracted the three-dimensional cloud atlas of beaver front tooth by laser scanning, obtain the cloud data of its surface geometry information, the cloud data obtained is filtered by the mode of setting and derives the file generating ASC II yard of form afterwards, and based on nurbs surface constructing curve; Described base configuration curved surface constructs topological rectangular mesh, mutual defined feature line, utilize rectangle data cancellated structure to go out beaver front tooth three-dimensional surface model;
Step 2, in described beaver front tooth three-dimensional surface model, determine knife face, beaver front tooth minor flank, beaver front tooth main cutting edge and beaver front tooth front cutting edge after beaver front tooth rake face, beaver front tooth master, and described beaver front tooth main cutting edge and beaver front tooth front cutting edge are projected on the basal plane of beaver front tooth, obtain drop shadow curve, matching is carried out to described drop shadow curve and obtains beaver front tooth cutting edge Fitting curve equation such as formula (1);
Knife face after beaver front tooth master and beaver front tooth minor flank at the orthogonal plane of beaver front tooth and perpendicular to orthogonal plane the transverse plane being parallel to basal plane are projected, obtain the vertical and horizontal drop shadow curve of knife face and beaver front tooth minor flank after beaver front tooth master respectively, to described vertical and horizontal drop shadow curve carry out respectively matching obtain beaver front tooth master after knife face and beaver front tooth minor flank Vertical Curve fit equation such as formula (2) and after obtaining beaver front tooth master the horizontal curve fit equation of knife face and beaver front tooth minor flank such as formula (3).
Compared with the prior art, beneficial effect of the present invention is embodied in: in the present invention, bionical Tool in Cutting efficiency is high, and long service life, cutting resistance are little.
Accompanying drawing explanation
Fig. 1 is billmpse tool and cutting movement schematic diagram thereof;
Fig. 2 billmpse tool cutter head schematic diagram;
The orthogonal plane referential of Fig. 3 billmpse tool cutting tip;
Fig. 4 is beaver front tooth diagram of block;
Fig. 5 is beaver front tooth cutting-edge projection curve map;
Fig. 6 is beaver front tooth back Vertical Curve figure;
Fig. 7 is beaver front tooth back horizontal curve figure;
Number in the figure: 1 rake face, 2 main rear knife faces, 3 minor flanks, 4 main cutting edges, 5 front cutting edges, 6 point of a knife points,
Detailed description of the invention
Be illustrated in figure 1 the billmpse tool T involved by the present embodiment and cutting movement signal thereof, the Vc in Fig. 1 is cutter direction of primary motion, V
ffor tool feeding direction, Ve is cutter resultant motion direction.
The tool bit part of the bionical cutter of the present embodiment turning is the bionical shape of beaver front tooth;
As shown in Figure 2, the cutting tip of the bionical cutter in the present embodiment has rake face 1, main rear knife face 2 and minor flank 3, and be in rake face 1 and main after main cutting edge 4 between knife face 2, be in front cutting edge 5 between rake face 1 and minor flank 3, rake face 1 and main after the intersection point that jointly formed between knife face 2 and minor flank 3 be point of a knife 6;
In the orthogonal plane referential of billmpse tool cutting tip as shown in Figure 3, Ps is cutting plane, and Po is orthogonal plane, and Pr is basal plane, and Ar is baseplane, and W is workpiece,
In the present embodiment, the curve shape of main cutting edge 4 and front cutting edge 5 characterizes by formula (1):
The main cutting edge 4 of bionical cutter and front cutting edge 5 are formed projection on cutter basal plane Pr face, and define X on cutter basal plane Pr face
1o
1y
1coordinate system, X
1o
1y
1coordinate system is the starting point of main cutting edge 4 in projecting is initial point, with tool feeding direction V
fto being X-axis, with in cutter basal plane Pr face perpendicular to tool feeding direction V
fto Tool in Cutting depth direction be Y direction; Then in formula (1):
X
1it is the coordinate value of the X-axis that main cutting edge 4 and front cutting edge 5 project on cutter basal plane Pr face;
Y
1it is the coordinate value of the Y-axis that main cutting edge 4 and front cutting edge 5 project on cutter basal plane Pr face;
After the master of bionical cutter, the Vertical Curve of knife face 2 and minor flank 3 characterizes by formula (2):
After the master of bionical cutter, the Vertical Curve of knife face 2 and minor flank 3 refers to the longitudinal profile line that main rear knife face 2 and minor flank 3 are formed in cutter orthogonal plane Po face; Cutter orthogonal plane Po face defines X
2o
2y
2coordinate system, X
2o
2y
2coordinate system is with the intersection point in main cutting edge 4, front cutting edge 5 and orthogonal plane Po face for initial point, in orthogonal plane Po face with the cutting speed Vc of cutter to opposite direction for X
2direction of principal axis, with the direction perpendicular to cutting speed Vc for Y
2direction of principal axis; Then in formula (2):
X
2lead the X that on rear knife face 2 and minor flank 3, longitudinal profile line projects on orthogonal plane Po face
2axial coordinate value;
Y
2lead the Y that on rear knife face 2 and minor flank 3, longitudinal profile line projects on orthogonal plane Po face
2axial coordinate value;
After the master of bionical cutter, the horizontal curve of knife face 2 and minor flank 3 characterizes by formula (3):
After the master of bionical cutter the horizontal curve of knife face 2 and minor flank 3 refer to main after knife face 2 and minor flank 3 being parallel to cutter basal plane Pr face and the horizontal section line formed in horizontal section by point of a knife point; Horizontal section defines X
3o
3y
3coordinate system, X
3o
3y
3coordinate system is with the intersection point of point of a knife point and horizontal section for initial point, with the direction of feed V of cutter
fto being X-axis, with in cutter basal plane Pr face perpendicular to direction of feed V
fto the cutting depth direction of cutter be Y direction; Then in formula (3):
X
3lead the X that on rear knife face 2 and minor flank 3, horizontal section line projects on horizontal section
3axial coordinate value;
Y
3lead the Y that on rear knife face 2 and minor flank 3, horizontal section line projects on horizontal section
3axial coordinate value.
The bionical cutter of the present invention changes conventional tool cutting edge straight line, rear knife face flat design, makes it in use can obtain minimum cutting resistance and higher service life.
As shown in Figure 4, according to the form that each position with cutting tool is corresponding, beaver front tooth rake face 1a is symbolized respectively for beaver front tooth, beaver front tooth front cutting edge 2a, beaver front tooth point of a knife point 3a, beaver front tooth main cutting edge 4a, the main minor flank 5a of beaver front tooth.
The method obtaining the bionical shape of beaver front tooth in the present embodiment is carried out as follows:
Step one, extracted the three-dimensional cloud atlas of beaver front tooth by laser scanning, obtain the cloud data of its surface geometry information, the cloud data obtained is filtered by the mode of setting and derives the file generating ASC II yard of form afterwards, and based on nurbs surface constructing curve; Base configuration curved surface constructs topological rectangular mesh, mutual defined feature line, utilize rectangle data cancellated structure to go out beaver front tooth three-dimensional surface model as shown in Figure 4;
Step 2, in described beaver front tooth three-dimensional surface model, determine knife face, beaver front tooth minor flank, beaver front tooth main cutting edge and beaver front tooth front cutting edge after beaver front tooth rake face, beaver front tooth master, and described beaver front tooth main cutting edge and beaver front tooth front cutting edge are projected on the basal plane of beaver front tooth, obtain drop shadow curve as shown in Figure 5, matching is carried out to described drop shadow curve and obtains beaver front tooth cutting edge Fitting curve equation such as formula (1);
Knife face after beaver front tooth master and beaver front tooth minor flank at the orthogonal plane of beaver front tooth and perpendicular to orthogonal plane the transverse plane being parallel to basal plane are projected, the longitudinal projection's curve obtaining knife face and beaver front tooth minor flank after beaver front tooth master respectively as shown in Figure 6 with transverse projection curve as shown in Figure 7, matching is carried out respectively to described vertical and horizontal drop shadow curve and obtains the Vertical Curve fit equation of knife face and beaver front tooth minor flank after beaver front tooth master such as formula (2), and the horizontal curve fit equation obtaining knife face and beaver front tooth minor flank after beaver front tooth master is such as formula (3).
Figure 5 shows that beaver front tooth cutting-edge projection curve map; Figure 6 shows that beaver front tooth back Vertical Curve figure; Figure 7 shows that beaver front tooth back horizontal curve figure.
Claims (1)
1. the bionical cutter of turning, is characterized in that the tool bit part of described bionical cutter is the bionical shape of beaver front tooth;
The part of the cutter head of described bionical cutter has rake face (1), main rear knife face (2) and minor flank (3), and be in described rake face (1) and main after main cutting edge (4) between knife face (2), be in front cutting edge (5) between described rake face (1) and minor flank (3), described rake face (1) is point of a knife point (6) with the common intersection point formed between main rear knife face (2) and minor flank (3); It is characterized in that:
The curve shape of described main cutting edge (4) and front cutting edge (5) characterizes by formula (1):
The main cutting edge (4) of described bionical cutter and front cutting edge (5) are formed projection on cutter basal plane Pr face, and define X on cutter basal plane Pr face
1o
1y
1coordinate system, described X
1o
1y
1coordinate system is with the starting point of main cutting edge (4) in described projection for initial point, with the direction of feed V of bionical cutter
fto being X-axis, with in bionical cutter basal plane Pr face perpendicular to direction of feed V
fto Tool in Cutting depth direction be Y direction; Then in formula (1):
X
1it is the coordinate value of the X-axis that main cutting edge (4) and front cutting edge (5) project on cutter basal plane Pr face;
Y
1it is the coordinate value of the Y-axis that main cutting edge (4) and front cutting edge (5) project on cutter basal plane Pr face;
After the master of described bionical cutter, the Vertical Curve of knife face (2) and minor flank (3) characterizes by formula (2):
The longitudinal profile line that after the Vertical Curve of knife face (2) and minor flank (3) refers to described master after the master of described bionical cutter, knife face (2) and minor flank (3) are formed in cutter orthogonal plane Po face; Cutter orthogonal plane Po face defines X
2o
2y
2coordinate system, described X
2o
2y
2coordinate system is with the intersection point in main cutting edge (4), front cutting edge (5) and orthogonal plane Po face for initial point, in orthogonal plane Po face with the cutting speed Vc of cutter to opposite direction for X
2direction of principal axis, with the direction perpendicular to cutting speed Vc for Y
2direction of principal axis; Then in formula (2):
X
2the X that main rear knife face (2) and the upper longitudinal profile line of minor flank (3) project on orthogonal plane Po face
2axial coordinate value;
Y
2the Y that main rear knife face (2) and the upper longitudinal profile line of minor flank (3) project on orthogonal plane Po face
2axial coordinate value;
After the master of described bionical cutter, the horizontal curve of knife face (2) and minor flank (3) characterizes by formula (3):
After after the master of described bionical cutter, the horizontal curve of knife face (2) and minor flank (3) refers to described master, knife face (2) and minor flank (3) are being parallel to cutter basal plane Pr face and the horizontal section line formed in horizontal section by point of a knife point; Described horizontal section defines X
3o
3y
3coordinate system, described X
3o
3y
3coordinate system is with the intersection point of point of a knife point and horizontal section for initial point, with the direction of feed V of cutter
fto being X-axis, with in cutter basal plane Pr face perpendicular to direction of feed V
fto the cutting depth direction of cutter be Y direction; Then in formula (3):
X
3the X that main rear knife face (2) and the upper horizontal section line of minor flank (3) project on horizontal section
3axial coordinate value;
Y
3the Y that main rear knife face (2) and the upper horizontal section line of minor flank (3) project on horizontal section
3axial coordinate value;
The bionical shape of described beaver front tooth obtains as follows:
Step one, extracted the three-dimensional cloud atlas of beaver front tooth by laser scanning, obtain the cloud data of its surface geometry information, the cloud data obtained is filtered by the mode of setting and derives the file generating ASC II yard of form afterwards, and based on nurbs surface constructing curve; Described base configuration curved surface constructs topological rectangular mesh, mutual defined feature line, utilize rectangle data cancellated structure to go out beaver front tooth three-dimensional surface model;
Step 2, in described beaver front tooth three-dimensional surface model, determine knife face, beaver front tooth minor flank, beaver front tooth main cutting edge and beaver front tooth front cutting edge after beaver front tooth rake face, beaver front tooth master, and described beaver front tooth main cutting edge and beaver front tooth front cutting edge are projected on the basal plane of beaver front tooth, obtain drop shadow curve, matching is carried out to described drop shadow curve and obtains beaver front tooth cutting edge Fitting curve equation such as formula (1);
Knife face after beaver front tooth master and beaver front tooth minor flank at the orthogonal plane of beaver front tooth and perpendicular to orthogonal plane the transverse plane being parallel to basal plane are projected, obtain the vertical and horizontal drop shadow curve of knife face and beaver front tooth minor flank after beaver front tooth master respectively, to described vertical and horizontal drop shadow curve carry out respectively matching obtain beaver front tooth master after knife face and beaver front tooth minor flank Vertical Curve fit equation such as formula (2) and after obtaining beaver front tooth master the horizontal curve fit equation of knife face and beaver front tooth minor flank such as formula (3).
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CN201310488882.6A CN103521791B (en) | 2013-10-18 | 2013-10-18 | The bionical cutter of a kind of turning |
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CN201310488882.6A Division CN103521791B (en) | 2013-10-18 | 2013-10-18 | The bionical cutter of a kind of turning |
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CN201510680544.1A Pending CN105149627A (en) | 2013-10-18 | 2013-10-18 | Cylindrical turning bionic cutter |
CN201310488882.6A Active CN103521791B (en) | 2013-10-18 | 2013-10-18 | The bionical cutter of a kind of turning |
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Cited By (2)
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CN107138751A (en) * | 2017-06-02 | 2017-09-08 | 安徽大学 | It is a kind of easily to import Bionics texture and cutter and design method |
CN109048080A (en) * | 2018-09-12 | 2018-12-21 | 基准精密工业(惠州)有限公司 | The laser processing of cutter |
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KR102156181B1 (en) * | 2016-07-18 | 2020-09-15 | 마이크로-램, 인코포레이티드 | Laser-transfer tooling |
CN107262812B (en) * | 2017-08-06 | 2023-04-07 | 吉林大学 | Bionic curved surface shearing knife |
CN108345715B (en) * | 2018-01-16 | 2020-03-17 | 西南交通大学 | Bionic design method for grinding head of colloid mill based on geometrical characteristics of bovine molar |
CN108763702B (en) * | 2018-05-18 | 2020-09-01 | 西南交通大学 | Bionic design method for depth gradient change micro-texture turning tool |
CN111673540A (en) * | 2020-06-19 | 2020-09-18 | 中国工程物理研究院机械制造工艺研究所 | Actual cutting-oriented diamond cutter cutting edge profile calculation method |
CN113695610B (en) * | 2021-09-03 | 2022-08-05 | 哈尔滨理工大学 | Bionic design method for labor-saving turning tool |
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Cited By (3)
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CN107138751A (en) * | 2017-06-02 | 2017-09-08 | 安徽大学 | It is a kind of easily to import Bionics texture and cutter and design method |
CN107138751B (en) * | 2017-06-02 | 2019-07-26 | 安徽大学 | It is a kind of easily to import Bionics texture and cutter and design method |
CN109048080A (en) * | 2018-09-12 | 2018-12-21 | 基准精密工业(惠州)有限公司 | The laser processing of cutter |
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CN103521791A (en) | 2014-01-22 |
CN103521791B (en) | 2015-11-18 |
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