CN102476333A - Cut tangent plane processing method - Google Patents
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- CN102476333A CN102476333A CN2010105593081A CN201010559308A CN102476333A CN 102476333 A CN102476333 A CN 102476333A CN 2010105593081 A CN2010105593081 A CN 2010105593081A CN 201010559308 A CN201010559308 A CN 201010559308A CN 102476333 A CN102476333 A CN 102476333A
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Abstract
The invention discloses a cut tangent plane processing method. The position parameters of a cut tangent plane to be processed are input into a controller by a human-computer interface, and the six position parameters of the cut tangent plane comprise a layer number, a layer angle, layer depth, a start angle, a halving number and a symmetry value; according to calculation, the controller firstly determines the position of the initial tangent plane of a cut workpiece; then, the position of each subsequent tangent plane is determined and output to control a corresponding driving motor; the cut workpiece on a fixture needle is positioned according to a required parameter; and the tangent plane is polished and grinded. In the cut tangent plane processing method, few tangent plane position parameters are input and calculated to obtain the spatial position parameters of multiple tangent planes, the multilayer and multi-tangent plane grinding and polishing operation of the cut workpiece is satisfied, input efficiency and input accuracy are improved, and meanwhile, the transportability of the cut processing parameters among different machine tables can be solved.
Description
Technical field
The invention belongs to a kind of grinding and polishing manufacture field, refer more particularly to a kind of input less parameters and can satisfy the sterically defined cut method for processing cut noodles of multiple sections.
Background technology
Present tangent plane shape cut workpiece is that wherein the degree of depth is the distance of tangent plane to board axle pivot by level number, layer angle, face angle and four parameter statements of degree of depth tangent plane position, and the face angle is the angle on tangent plane and girdle plane; Because each tangent plane all need be imported four parameters; When processing the number of plies or tangent plane more for a long time, then need import lot of data, need import 2 * 50 * 4=400 parameter like the statement of 2 layers of 50 cut; The parameter input quantity is huge; Input process is prone to make mistakes, difficult inspection and location, is unfavorable for the directly perceived demonstration of parameter at inputting interface, more is unfavorable for accurately locating the parameter of cut arbitrary face or to the change of parameter.
Summary of the invention
The present invention solves mainly that existing cut processing tangent plane parameter input quantity is huge, input process is prone to make mistakes, be not easy the accurate technical problem of location or change of parameter; A kind of cut processing method for processing cut noodles that less parameters can satisfy the multiple sections location of importing is provided.
In order to solve the technical problem of above-mentioned existence, the present invention adopts following technical proposals:
A kind of cut method for processing cut noodles of the present invention, said cut workpiece divides girdle, bizet and booth portion, and said bizet is made up of several layers polylith tangent plane, and said booth portion is made up of several layers polylith tangent plane, and the processing method of cut tangent plane may further comprise the steps:
1) cut tangent plane location parameter to be processed is input in the controller through man-machine interface; Said tangent plane location parameter is 6, and comprise level number, layer angle, layer depth, initial angle, isodisperse, symmetry value: the tangent space position is (degree of depth, angle I, angle II);
2) confirm first tangent space position of ground floor (degree of depth, layer angle, initial angle), and parameter is stored in the memory of initial tangent plane position: the initial position of processing, level number 1 expression ground floor tangent plane;
3) confirm second tangent space position of ground floor (layer depth, angle I, angle II), and store in the ground floor follow-up location memory;
4) confirm the space position parameter of all the other tangent planes of ground floor by above method, and store respectively in the memory of the follow-up tangent plane of ground floor position;
5) by that analogy, confirm that the second layer reaches the space position parameter with the corresponding tangent plane in upper strata, and store respectively in the memory of equivalent layer tangent plane position;
6) after calculating finishes; Controller is earlier with the initial tangent space location parameter output of ground floor; Worm and gear device drive motors or runing rest drive motors in the control clamp body; Confirm the initial tangent space of workpiece position, the mill that the workpiece that makes anchor clamps pin top initial tangent plane parameter is on request accomplished the location and carried out initial tangent plane is cut or polishing operation;
7) then, controller is exported the follow-up tangent plane parameter of ground floor successively, and the worm and gear device drive motors in the control clamp body makes workpiece rotate the mill of accomplishing follow-up tangent plane successively and cuts or polishing operation;
8) by that analogy; Controller is exported the follow-up tangent plane parameter of the second layer successively; The angle of control clamp body runing rest is confirmed the inclined degree of anchor clamps pin; Reach the layer angle of equivalent layer, and and then the control clamp body in worm and gear device drive motors, workpiece is rotated successively accomplish the second layer and cuts or polishing operation with the mill of the corresponding follow-up tangent plane in upper strata.
As preferably, said level number is the machined layer numbering of cut workpiece;
Said layer angle is the slanted angle of machined layer and girdle horizontal plane;
Said layer depth is the vertical range of processing tangent plane and girdle horizontal plane central point;
Said initial angle is the angle of first processing tangent plane and girdle horizontal plane central point imagination zero degree vertical plane;
Said isodisperse is every layer of all processing tangent plane number, and the processing tangent plane is divided equally along the circumference angle;
Said symmetry be tangent plane along imaginary zero degree vertical plane mirror to being symmetrical set.
As preferably, when symmetry value=0, the tangent space position is (degree of depth, angle I, an angle II),
Wherein: the degree of depth=layer depth;
Angle I=layer angle;
Angle II=initial angle+(360/ isodisperse) * (N-1);
When symmetry value=1, the tangent space position is (degree of depth, angle I, an angle II)
Wherein: the degree of depth=layer depth;
Angle I=layer angle;
Angle II=initial angle+(360/ isodisperse) * (N-1);
Or angle II=360-(initial angle+((360/ isodisperse) * (N-1));
N=1,2 ..., isodisperse.
As preferably, the man-machine interface of said tangent plane parameter input flow process is following:
1) at first by level number, layer angle, layer depth, the initial angle of the initial tangent plane of form input ground floor: the space position parameter of confirming initial tangent plane;
2) input isodisperse: confirm the anglec of rotation of tangent plane on circumference, the corresponding space position parameter of confirming follow-up tangent plane;
3) input symmetric parameter :=1, symmetry, tangent plane by false to zero degree vertical plane mirror to symmetry, add
Worker's tangent plane number is two times of isodisperse;
=0, asymmetric; Processing tangent plane number is isodisperse;
4) press the location parameter that above step is imported each tangent plane of the second layer:
5) import the 3rd layer of location parameter that reaches with each tangent plane of upper strata successively.
As preferably, said position memory is E
2PROM can satisfy the storage change requirement of the tangent plane location parameter of different workpieces processing.
The invention has the beneficial effects as follows: through importing less tangent plane location parameter and calculating; Draw the space position parameter of multiple sections; Satisfying the mill of cut workpiece multilayer multiple sections cuts and polishing operation; Improve input efficiency and accuracy rate, solved the portability of cut machined parameters between the different platform simultaneously.
Description of drawings
Fig. 1 is a kind of cut workpiece perspective view of the present invention;
Fig. 2 is the front view of Fig. 1;
Fig. 3 is the vertical view of Fig. 1;
Fig. 4 is a man-machine interface input tabular drawing of the present invention;
Fig. 5 is a man-machine interface input flow chart of the present invention;
1. cut workpiece among the figure, 11. bizets, 12. girdles, 13. booth portions, 14. tangent planes.
The specific embodiment
Pass through embodiment below, and combine accompanying drawing, do further bright specifically technical scheme of the present invention.
Embodiment: a kind of cut method for processing cut noodles of present embodiment; Like Fig. 1, Fig. 2 and shown in Figure 3, the cut workpiece divides bizet, girdle and booth portion, bizet by eight tangent planes of one deck around forming; Booth portion by 16 tangent planes of one deck around constituting; The cut method for processing cut noodles, as shown in Figure 5, may further comprise the steps:
1) cut tangent plane location parameter to be processed is input in the controller through man-machine interface, the tangent plane location parameter is 6, comprises level number, layer angle, layer depth, initial angle, isodisperse, symmetry value; Level number is the machined layer numbering of cut workpiece; Layer angle is the slanted angle of machined layer and girdle horizontal plane; Layer depth is the vertical range of processing tangent plane and girdle horizontal plane central point; Initial angle is the angle of first processing tangent plane and girdle horizontal plane central point imagination zero degree vertical plane; Isodisperse is every layer of all processing tangent plane number, and the processing tangent plane is divided equally along the circumference angle; Symmetry be tangent plane along imaginary zero degree vertical plane mirror to being symmetrical set; The tangent space position is (degree of depth, angle I, an angle II);
2) through four parameters in the tangent plane location parameter, promptly level number, layer angle, layer depth, initial angle are confirmed the space position parameter of first tangent plane of cut workpiece bandit portion, and parameter is stored E
2Among the PROM: tangent space position (layer depth, layer angle, initial angle);
3) through two parameters in addition in the tangent plane parameter, i.e. isodisperse and symmetry value through calculating the anglec of rotation of second tangent plane of bizet with respect to initial tangent plane, and then are confirmed the space position parameter of second tangent plane, and are stored E
2Among the PROM;
4) confirm the space position parameter of all the other tangent planes of bizet by above method, and store E respectively
2Among the PROM;
5) by that analogy, confirm the space position parameter of first tangent plane of cut workpiece booth portion, and store equivalent layer E respectively
2Among the PROM;
6) after calculating finishes; Controller is earlier with the initial tangent space location parameter output of bizet; Worm and gear device drive motors and runing rest drive motors in the control clamp body; Confirm the initial tangent space of workpiece position, the mill that the workpiece that makes anchor clamps pin top initial tangent plane parameter is on request accomplished the location and carried out initial tangent plane is cut or polishing operation;
7) then, controller is exported the follow-up tangent plane parameter of bandit portion successively, the worm and gear device drive motors in the control clamp body, and the mill that makes workpiece rotate all the other tangent planes of completion bandit portion is successively cut or polishing operation;
8) by that analogy; Controller is exported the follow-up tangent plane parameter of booth portion successively; The angle of control clamp body runing rest is confirmed the inclined degree of anchor clamps pin; Reach the layer angle of booth portion tangent plane, and and then the control clamp body in worm and gear device drive motors, workpiece is rotated successively accomplish the mill of all the other follow-up tangent planes of booth portion to be cut or polishing operation;
When symmetry value=0, the tangent space position is (degree of depth, angle I, an angle II),
Wherein: the degree of depth=layer depth;
Angle I=layer angle;
Angle II=initial angle+(360/ isodisperse) * (N-1);
When symmetry value=1, the tangent space position is (degree of depth, angle I, an angle II)
Wherein: the degree of depth=layer depth;
Angle I=layer angle;
Angle II=initial angle+(360/ isodisperse) * (N-1);
With angle II=360-(initial angle+(360/ isodisperse) * (N-1));
N=1,2 ..., isodisperse
The man-machine interface input flow process of tangent plane parameter, as shown in Figure 4, may further comprise the steps:
1) at first by level number, layer angle, layer depth, the initial angle of the initial tangent plane of form input ground floor: the space position parameter of confirming initial tangent plane;
2) input isodisperse: confirm the anglec of rotation of tangent plane on circumference, the corresponding space position parameter of confirming follow-up tangent plane;
3) input symmetric parameter :=1, symmetry then, tangent plane by false to zero degree vertical plane mirror to symmetry, processing tangent plane number is two times of isodisperse;
=0, asymmetric, processing tangent plane number is isodisperse;
4) press the location parameter that above step is imported each tangent plane of the second layer:
5) import the 3rd layer of location parameter that reaches with each tangent plane of upper strata successively:
When the grinding and polishing of cut workpiece adds man-hour; At first cut workpiece tangent plane parameter to be processed is imported in the controller through man-machine interface; The bandit portion of cut workpiece is the individual layer tangent plane; Level number is 1, and layer angle is 30 °, and layer depth is 20mm; Initial angle is 0 °; Isodisperse is 8 o'clock, and the space position parameter of initial tangent plane is (20,30 °, 30 °), and symmetry value is 0; Then all the other follow-up tangent space location parameters are followed successively by (20,30 °, 45 °), (20,30 °, 90 °), (20,30 °, 135 °), (20,30 °, 180 °), (20,30 °, 225 °), (20,30 °, 270 °), (20,30 °, 315 °), (20,30 °, 360 °); And the booth portion of cut workpiece also is the individual layer tangent plane, and layer angle is-45 °, and layer depth is 35mm; Initial angle is 10 °; Isodisperse is 8, and symmetry value is 1, and then booth portion tangent space parameter is followed successively by (35 ,-45 °, 10 °), (35 ,-45 °, 55 °), (35 ,-45 °, 100 °), (35 ,-45 °, 145 °), (35 ,-45 °, 190 °), (35 ,-45 °, 235 °), (35 ,-45 °, 280 °), (35 ,-45 °, 325 °); Add the tangent plane to symmetry on show (35 ,-45 °, 350 °), (35 ,-45 °, 305 °), (35 ,-45 °, 260 °), (35 ,-45 °, 215 °), (35 ,-45 °, 170 °), (35 ,-45 °, 125 °), (35 ,-45 °, 80 °), (35 ,-45 °, 35 °) 16 tangent planes altogether, above tangent space parameter is stored in E
2PROM controls the output of tangent plane parameter the tangent plane grinding and polishing operation of corresponding driving motor and then control cut workpiece then.
More than explanation is not that the present invention has been done restriction; The present invention also is not limited only to giving an example of above-mentioned explanation; The variation that those skilled in the art have done in essential scope of the present invention, retrofit, increase or replace, all should be regarded as protection scope of the present invention.
Claims (5)
1. cut method for processing cut noodles; Said cut workpiece divides girdle, bizet and booth portion; Said bizet is made up of several layers polylith tangent plane, and said booth portion is made up of several layers polylith tangent plane, and be primarily characterized in that: the location parameter computational methods of cut tangent plane may further comprise the steps:
1) cut tangent plane location parameter to be processed is input in the controller through man-machine interface; Said tangent plane location parameter is 6, and comprise level number, layer angle, layer depth, initial angle, isodisperse, symmetry value: the tangent space position is (degree of depth, angle I, angle II);
2) confirm first tangent space position of ground floor (degree of depth, layer angle, initial angle), and parameter is stored in the memory of initial tangent plane position: the initial position of processing, level number 1 expression ground floor tangent plane;
3) confirm second tangent space position of ground floor (layer depth, angle I, angle II), and store in the ground floor follow-up location memory;
4) confirm the space position parameter of all the other tangent planes of ground floor by above method, and store respectively in the memory of the follow-up tangent plane of ground floor position;
5) by that analogy, confirm that the second layer reaches the space position parameter with the corresponding tangent plane in upper strata, and store respectively in the memory of equivalent layer tangent plane position;
6) after calculating finishes; Controller is earlier with the initial tangent space location parameter output of ground floor; Worm and gear device drive motors or runing rest drive motors in the control clamp body; Confirm the initial tangent space of workpiece position, the mill that the workpiece that makes anchor clamps pin top initial tangent plane parameter is on request accomplished the location and carried out initial tangent plane is cut or polishing operation;
7) then, controller is exported the follow-up tangent plane parameter of ground floor successively, and the worm and gear device drive motors in the control clamp body makes workpiece rotate the mill of accomplishing follow-up tangent plane successively and cuts or polishing operation;
8) by that analogy; Controller is exported the follow-up tangent plane parameter of the second layer successively; The angle of control clamp body runing rest is confirmed the inclined degree of anchor clamps pin; Reach the layer angle of equivalent layer, and and then the control clamp body in worm and gear device drive motors, workpiece is rotated successively accomplish the second layer and cuts or polishing operation with the mill of the corresponding follow-up tangent plane in upper strata.
2. a kind of cut method for processing cut noodles according to claim 1 is characterized in that:
Said level number is the machined layer numbering of cut workpiece;
Said layer angle is the slanted angle of machined layer and girdle horizontal plane;
Said layer depth is the vertical range of processing tangent plane and girdle horizontal plane central point;
Said initial angle is the angle of first processing tangent plane and girdle horizontal plane central point imagination zero degree vertical plane;
Said isodisperse is every layer of all processing tangent plane number, and the processing tangent plane is divided equally along the circumference angle;
Said symmetry be tangent plane along imaginary zero degree vertical plane mirror to being symmetrical set.
3. a kind of cut method for processing cut noodles according to claim 1 and 2 is characterized in that:
When symmetry value=0, the tangent space position is (degree of depth, angle I, an angle II),
Wherein: the degree of depth=layer depth;
Angle I=layer angle;
Angle II=initial angle+(360/ isodisperse) * (N-1);
When symmetry value=1, the tangent space position is (degree of depth, angle I, an angle II)
Wherein: the degree of depth=layer depth;
Angle I=layer angle;
Angle II=initial angle+(360/ isodisperse) * (N-1);
Or angle II=360-[ initial angle+(360/ isodisperse) * (N-1) ];
N=1,2 ..., isodisperse.
4. a kind of cut method for processing cut noodles according to claim 1 is characterized in that: the man-machine interface input flow process of said tangent plane parameter is following:
1) at first by level number, layer angle, layer depth, the initial angle of the initial tangent plane of form input ground floor: the space position parameter of confirming initial tangent plane;
2) input isodisperse: confirm the anglec of rotation of tangent plane on circumference, the corresponding space position parameter of confirming follow-up tangent plane;
3) input symmetric parameter :=1, symmetry, tangent plane by false to zero degree vertical plane mirror to symmetry, processing tangent plane number is two times of isodisperse;
=0, asymmetric; Processing tangent plane number is isodisperse;
4) press the location parameter that above step is imported each tangent plane of the second layer:
5) import the 3rd layer of location parameter that reaches with each tangent plane of upper strata successively.
5. a kind of cut method for processing cut noodles according to claim 1 is characterized in that: said position memory is E
2PROM.
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| CN2010105593081A CN102476333A (en) | 2010-11-25 | 2010-11-25 | Cut tangent plane processing method |
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|---|---|---|---|
| CN2010105593081A CN102476333A (en) | 2010-11-25 | 2010-11-25 | Cut tangent plane processing method |
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Citations (7)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US5722261A (en) * | 1996-11-13 | 1998-03-03 | Lehrer; Glenn W. | Torous ring gemstone and method for making same |
| JP2000005993A (en) * | 1998-06-17 | 2000-01-11 | Hisatake Shudo | Cutting method for diamond and proportion of diamond |
| CN1340321A (en) * | 2000-08-25 | 2002-03-20 | 株式会社微笑智能 | Cutting structure for decorative diamond |
| CN1721134A (en) * | 2005-01-04 | 2006-01-18 | 桂林工学院 | Groove inside reflection type jewel machining process |
| JP3138424U (en) * | 2007-06-01 | 2008-01-10 | ヴァーグ株式会社 | 72-sided proportion diamond |
| CN101155665A (en) * | 2005-02-17 | 2008-04-02 | 戴亚来特有限公司 | Means and method of computer-aided manufacturing of polished gemstones from rough or semi processed gemstones |
| CN101793840A (en) * | 2010-03-29 | 2010-08-04 | 中国地质大学(武汉) | Diamond cutting parameter measurement method and measuring device |
-
2010
- 2010-11-25 CN CN2010105593081A patent/CN102476333A/en active Pending
Patent Citations (7)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US5722261A (en) * | 1996-11-13 | 1998-03-03 | Lehrer; Glenn W. | Torous ring gemstone and method for making same |
| JP2000005993A (en) * | 1998-06-17 | 2000-01-11 | Hisatake Shudo | Cutting method for diamond and proportion of diamond |
| CN1340321A (en) * | 2000-08-25 | 2002-03-20 | 株式会社微笑智能 | Cutting structure for decorative diamond |
| CN1721134A (en) * | 2005-01-04 | 2006-01-18 | 桂林工学院 | Groove inside reflection type jewel machining process |
| CN101155665A (en) * | 2005-02-17 | 2008-04-02 | 戴亚来特有限公司 | Means and method of computer-aided manufacturing of polished gemstones from rough or semi processed gemstones |
| JP3138424U (en) * | 2007-06-01 | 2008-01-10 | ヴァーグ株式会社 | 72-sided proportion diamond |
| CN101793840A (en) * | 2010-03-29 | 2010-08-04 | 中国地质大学(武汉) | Diamond cutting parameter measurement method and measuring device |
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