游戲機(jī)手柄注塑模具成型部件數(shù)控加工編程帶開題報(bào)告.zip
游戲機(jī)手柄注塑模具成型部件數(shù)控加工編程帶開題報(bào)告.zip,游戲機(jī),手柄,注塑,模具,成型,部件,數(shù)控,加工,編程,開題,報(bào)告
Computer Aided Design that is to say that the voxel falling in the cutter should be eliminated If part of the vertices fall inside and the others outside it means the voxel needs to be further divided For each subdivided voxel step 2 and step 3 will be carried out recursively until a predetermined precision level is reached After the current segment of the NC path is finished step 1 is performed again and the next segment of the NC code is read The procedure is followed to the end until all NC codes have been read In the procedure for three axis machining simulation mentioned above it is clear that voxels are subdivided as needed according to the geometric relationship between the cutter and the workpiece a large number of voxels are not created all at once in the beginning Fig 7 shows that voxels in contact only with a ball endmill will be subdivided by the octree Voxels not in contact with the cutter will not be subdivided Thus this approach greatly reduces the number of voxels and saves memory during simulation Fig 7 Three axis NC machining simulation In comparison with z map model NC simulation using voxel model can display multi axis machining result The dexel model has the restriction of being view dependent but the voxel model does not have this restriction Thus three axis five side machining can utilize the three axis simulation method of this paper as Fig 8 shows Computer Aided Design Applications Vol 2 Nos 1 4 2005 pp 95 104 100 Fig 8 Example of three axis and five side simulation 5 SIMULATION OF FIVE AXIS NC MACHINING In five axis NC machining in addition to the three translation movements the tool axis can also be rotated Therefore our approach to five axis simulation only revises the implicit function of the cutter All other procedures are the same as the three axis simulation Thus the three kinds of cutters can be expressed as follows Flat endmills can be represented by a cylinder Fig 9 shows that the tool axis is along n and the center point is located at p Thus the implicit function of a flat endmill is 2 2 0 T TF X Y Z x p n x p R if n x p L 5 where R the cutter radius Tx X Y Z the position of a voxel vertex Tx y zn n n n the unit vector of the tool axis Tx y zp p p p the center point 2 2 2 2 10 0 1 0 1 x x y x zz y z x x y y y z y x x z y z z n n n n nn n n n n n n n n n n n n n n n n n Fig 9 Flat endmill rotated in five axis mode Computer Aided Design Applications Vol 2 Nos 1 4 2005 pp 95 104 101 Ball endmills can be represented by the union of a cylinder and a sphere Fig 10 shows that the tool axis is along n and the center point is located at p Thus the implicit function of a ball endmill is 2 2 2 0 T T T x p n x p R if n x p LF X Y Z x p x p R otherwise 6 where R the cutter radius n the unit vector of the tool axis Fig 10 Ball endmill rotated in five axis mode Fillet endmills can be represented by the union of two cylinders and a torus Fig 11 shows that the tool axis is along n and that the center point is located at p Thus the implicit function of a round endmill is 2 2 2 2 2 2 22 2 2 2 2 2 0 0 and 4 T T T T T T T T v n v R r if n v L else if n v r n rF X Y Z v n v R v n v R v n v n v R r R v n v otherwise 7 where R the radial distance from the cutter axis to the cutter corner center r the cutter corner radius n the unit vector of the tool axis v x p Fig 11 Fillet endmill rotated in five axis mode Computer Aided Design Applications Vol 2 Nos 1 4 2005 pp 95 104 102 Fig 12 shows a simple example of a cutter axis rotated from 70 degrees to 50 degrees about the x axis and moved along the x axis Fig 13 shows the tool paths and simulation process used for five axis machining of an impeller Fig 14 shows another example of five axis machining simulation of a blade Fig 12 Five axis machining simulation a b c d Fig 13 Example of impeller in five axis simulation a Tool paths b c In process workpiece with a cutter d Finished part Computer Aided Design Applications Vol 2 Nos 1 4 2005 pp 95 104 103 a b c d Fig 14 Example of blade in five axis simulation a Tool paths b c In process workpiece with a cutter d Finished part 6 EXPERIMENTAL RESULTS The proposed method has been implemented in C and some test cases were run on a 2 4 GHZ Pentium 4 computer Tab 1 gives a comparison of the required memory space and computation time for adaptive NC simulation The first row shows the pictures of NC path for four different models The second and third rows show the information of NC code The fourth row is the resolution of the workpiece model The cutter models are presented by implicit functions exactly so there is no accuracy issue here The fifth row shows the types of cutter being used The last three rows are the required memory space computation time and the rendered simulation result Part Impeller Blade Shoe Bottle NC path Number of NC code line 2654 2536 74803 3340 Length of NC code mm 24950 8642 27287 3060 Resolution mm 0 1 0 1 0 1 0 1 Cutting tool Flat R3 Ball R10 Flat R1 5 Ball R1 Computation time Sec 562 387 296 209 Memory space MB 192 101 67 132 Simulation result Tab 1 Required memory space and computation time for adaptive NC simulation Computer Aided Design Applications Vol 2 Nos 1 4 2005 pp 95 104 104 Tab 2 gives a comparison of the required memory space and computation time for NC simulation using uniform voxel models The parameters remain the same as adaptive NC simulation Under this condition we are not able to simulate case1 Impeller and case3 shoe because such cases exceed our memory limitation The results that can be observed are case 2 blade and case 4 bottle By comparison the advantage of the adaptive NC simulation is clear A great reduction of time and space can be achieved by using the adaptive NC simulation Part Impeller Blade Shoe Bottle Computation time Sec X 1491 X 721 Memory space MB X 414 X 380 Tab 2 Required memory space and computation time for NC simulation with uniform voxel model 7 CONCLUSION In this paper we proposed a novel multi axis simulation method The objective of this paper was to use the adaptive voxel model to develop a reliable multi axis simulation procedure which can simulate the cutting route and the workpiece appearance during and after the simulation It allows the user to do error analysis and comparison between the cutting model and the original CAD model It can verify the accuracy of NC codes before machining on a CNC machine in order to avoid wasting material and to improve machining accuracy In summary the advantages of the multi axis simulation method presented in this paper are as follows 1 The simulation method uses less memory than other voxel based simulation methods 2 The simulation is view independent The dexel model has the restriction of being view dependent but the voxel model does not have this restriction 3 The simulation is reliable and accurate Regardless of whether it is the five axis or three axis simulation which uses the implicit function to represent a cutter the whole method is simple and reliable 8 REFERENCES 1 Choi B K Jerard R B Sculptured Surface Machining Theory and Applications Kluwer Academic Publishers 1998 2 Wang W P Wang K K Geometric Modeling for Swept Volume of Moving Solids IEEE Computer Graphics Applications Vol 6 No 12 1986 pp 8 17 3 Atherton P R A Scan Line Hidden Surface Removal Procedure for Constructive Solid Geometry Computer Graphics Vol 17 No 3 1983 pp 73 82 4 Kawashima Y Itoh K Ishida T Nonaka S Ejiri K A Flexible Quantitative Method for NC Machining Verification Using a Space Division Based Solid Model The Visual Computer Vol 7 1991 pp 149 157 5 Jang D Kim K Jung J Voxel Based Virtual Multi Axis Machining Advanced Manufacturing Technology Vol 16 No 10 2000 pp 709 713 6 Van Hook T Real Time Shaded NC Milling Display Computer Graphics Vol 20 No 4 1986 pp 15 20 7 Huang Y Oliver J H Integrated Simulation Error Assessment and Tool Path Correction for Five Axis NC Milling Journal of Manufacturing Systems Vol 14 No 5 1995 pp 331 334 8 Saito T Takahashi T NC Machining with G buffer Method Computer Graphics Vol 25 1991 pp 207 216 9 Chang K Y Goodman E D A Method for NC Tool Path Interference Detection for A Multi Axis Milling System ASME Control of Manufacturing Process DSC Vol 28 PED Vol 52 1991 pp 23 30 10 Oliver J H Goodman E D Direct Dimensional NC Verification Computer Aided Design Vol 22 No 1 1990 pp 3 10 11 Jerard R B Drysdale R L Hauck K Schaudt B Magewick J Methods for Detecting Errors in Numerically Controlled Machining of Sculptured surface IEEE Computer Graphics Applications Vol 9 No 1 1989 pp 26 39 12 Yamaguchi K Kunii T Fujimura K Octree Related Data Structures and Algorithms IEEE Computer Graphics Appl Vol 8 No 3 1984 pp 8 68 13 Glaeser G Gr ller E Efficient Volume Generation During the Simulation of NC Milling Mathematical Visualization 1997 pp 315 328 14 Chung Y C Park J W Shin H Choi B K Modeling the Surface Swept by a Generalized Cutter for NC Verification Computer Aided Design Vol 30 No 8 1996 pp 587 94
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游戲機(jī)
手柄
注塑
模具
成型
部件
數(shù)控
加工
編程
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游戲機(jī)手柄注塑模具成型部件數(shù)控加工編程帶開題報(bào)告.zip,游戲機(jī),手柄,注塑,模具,成型,部件,數(shù)控,加工,編程,開題,報(bào)告
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