CN1178763C - Method for making miniature cutter and stereo microstructure - Google Patents
Method for making miniature cutter and stereo microstructure Download PDFInfo
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- CN1178763C CN1178763C CNB011042281A CN01104228A CN1178763C CN 1178763 C CN1178763 C CN 1178763C CN B011042281 A CNB011042281 A CN B011042281A CN 01104228 A CN01104228 A CN 01104228A CN 1178763 C CN1178763 C CN 1178763C
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- cutter
- stereo microstructure
- microstructure
- making
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Abstract
The present invention discloses a method for making a miniature cutter and a stereo microstructure. Cutting is carried out by the miniature cutter on the surface of a processed material to process out the shape which is opposite to a section shape at the cutting position of the miniature cutter. The making method of the miniature cutter comprises the steps that a light resistance agent is coated on a plane base board, and a microimage of the light resistance agent forms a casting mold which has the corresponding shape with the miniature cutter. The miniature cutter is electroformed by the casting mold and is arranged in a mode that the miniature cutter is perpendicular to the surface of the processed material. A miniature stereo structure is cut out on the surface of the processed material. The production rate of the stereo microstructure can be largely enhanced, and the production cost is lowered.
Description
Technical field
The present invention relates to a kind of method of making min-cutter and stereo microstructure, be meant that especially a kind of min-cutter that utilizes adopts planing or milling mode be shaped the making min-cutter of miniature spatial structure and the method for stereo microstructure on plane machined object.
Background technology
In optical-fibre communications, photoelectric display field, usually must make micromachine with machining or in the chemical etching mode, this micromachine has three-dimensional three-dimensional (3D) microstructure usually in the surface, for example: the V-groove (V-groove) on backlight liquid crystal display module, preceding optical mode group (fresnel lens), grating (blazedgrating), the grating type DWDM, the 3D microstructure on the U type groove planes such as (U-groove).
Usually in order to the method for the 3D microstructure of processing the type, nothing more than two kinds of methods such as traditional machining and chemical etchings.Wherein, use machining, it mainly is to use cutting tool to cut the shape of needed stereo microstructure on the surface of machined object, when using machining, the precision of the size and shape of this kind microstructure is the precision that depends on cutter and processing equipment fully, yet its precision of general machining is merely able to reach the precision of one of percentage centimetre usually, and comparatively accurate machinery also is merely able to reach the precision of per mille centimetre at most, therefore the stereo microstructure that comes out with the machining process manufacturing, its precision can't meet optical-fibre communications now and the desired precision of photoelectric display product.And, the forming tool that the traditional mechanical job operation is used also must create with the mode of mechanical lapping, as shown in Figure 9, part at the most advanced and sophisticated 1A and the re-entrant angle 1B of forming tool 1, because be subject to the restriction of milling cutter instrument, usually all can leave fillet partly, make the position of this tip 1A and re-entrant angle 1B can't become sharp shape completely, can form arc, therefore the stereo microstructure that makes forming tool 1 be processed also can't reach absolute sharp shape in the inside lock position of wedge angle or groove, can leave arc partly, had influence on the size accuracy of stereo microstructure, also variation of the numerous shape of stereo microstructure simultaneously, V-groove as preceding light guide plate can reach thousands of to tens thousand of, and the microstructure of module light guide plate backlight has semisphere, pyramid makes that the making of forming tool is difficult more.
In addition, stereo microstructure with the method for chemially etching made, be with the mode of the little development of photoresistance develop the earlier a part of shape of stereo microstructure in the surface of machined object, with the chemical agent etching the little again shadow of this machined object is gone out the photoresistance pattern of other one groove then, and then etch the shape of other one groove, so repetitiousness ground repeats little development and etched operation on the surface of machined object, can produce three-dimensional microstructure on the surface of machined object.For example Figure 10 is to shown in Figure 15, when using engraving method to produce the complex micro structure shape of similar fresnel lens and so on, must coat photoresist 3 on the surface of machined object 2 earlier, little then shadow goes out the photoresistance pattern 4 (as shown in figure 11) of one groove, etch a groove 5 with chemical agent as illustrated in fig. 12 then, and then repeat as illustrated in fig. 13 to coat photoresist 3 in the surface of machined object 2 again, etch the different groove 5A of other one degree of depth more as illustrated in fig. 14 in the next door of groove 5, so through repeatedly etching program, produce the groove of multiple tracks different depth on the surface of machined object 2, so can go out the microstructure of a solid, and form the structure of a fresnel lens as shown in figure 15 by these some groove combination.
Yet because method for chemially etching is when making the comparatively complicated stereo microstructure of some shape, because stereo microstructure its shape usually is quite complicated, therefore, must can enough be shaped through little development and etched program repeatedly, therefore make that the speed of production of the microstructure of making in the chemical etching mode is quite slow, make it can not be suitable for producing in enormous quantities, and make its manufacturing cost quite expensive, etched surface is stepped, can't make continuous inclined-plane or curved surface.Because more than, make existing technological means have sizable shortcoming in the use in order to the making stereo microstructure.
Summary of the invention
Fundamental purpose of the present invention is to provide a kind of method for making of min-cutter, and it can increase the variation of min-cutter shape, improves the dimensional accuracy of min-cutter, thereby overcomes the shortcoming that the traditional mechanical job operation is made min-cutter.
Another object of the present invention is to provide a kind of method of making min-cutter and stereo microstructure, it can produce stereo microstructure in enormous quantities fast with machining process, improves speed of production, reduces production costs.
The object of the present invention is achieved like this: a kind of method of making stereo microstructure comprises the following steps:
A. with the photoetching mould of method for photolithography making one in order to the forming tool of shaping stereo microstructure;
B. with the electrocasting method min-cutter that in this photoetching mould, is shaped;
C. this min-cutter is installed on the machining tool, and utilizes this min-cutter that one machined object is cut, the stereo microstructure that has corresponding shape in this machined object shaping surface one and this min-cutter.
This min-cutter cuts on this machined object with linear cutting way.
This min-cutter cuts on this machined object with rotation mode.
The material of this min-cutter is to select high hardness material.
High hardness material is nickel or Rhometal or nickel cobalt (alloy) or nickel tungsten or nickel and carbonization silicon synthetic material.
A kind of method in order to the min-cutter of making stereo microstructure, min-cutter has and the corresponding cutting edge shape of aforementioned stereo microstructure, this min-cutter has identical shaped photoetching mould by make one in little shadow mode on a planar substrates with this min-cutter, then with electroforming mode this min-cutter that is shaped in this photoetching mould.
The material of this min-cutter is to select high hardness material.
High hardness material is nickel or Rhometal or nickel cobalt (alloy) or nickel tungsten or nickel and carbonization silicon synthetic material.
Above-mentioned technological means of the present invention, compare with the stereo microstructure of existing mechanical processing mode made, because being the technological means manufacturing with little shadow photoetching mould and electroforming, the min-cutter of its use forms, make this min-cutter have splendid size and shape precision, and because this min-cutter is not to use the machining mode to make to form, therefore it can not be subject to the shortcoming that the machining mode will inevitably stay circular shape in the wedge angle of cutter and the position of inside lock, have the sharp-pointed wedge angle or the sharp-pointed stereo microstructure of the shape of inside lock so that the min-cutter that comes out with made of the present invention can process.
Have again, the present invention compares with existing technology with method for chemially etching manufacturing stereo microstructure, because it is to use min-cutter to carry out the processing of stereo microstructure, and this min-cutter can be in cutting process, process whole shapes of stereo microstructure, therefore can avoid existing method for chemially etching to expose over and over again and can enough make the shortcoming of the shape of stereo microstructure with etched program, and it can also carry out continuous repeated production work in the machining mode speed and conveniencely, therefore make method of the present invention can improve the speed of production of stereo microstructure significantly, and reduce its production cost.
Description of drawings
Fig. 1 to Fig. 5 is the making flow process of the min-cutter of the present invention's use and the synoptic diagram of method for making.
Fig. 6 is the stereographic map of the min-cutter of the present invention's use.
Fig. 7 is the stereographic map of the embodiment that utilizes min-cutter of the present invention and cut with linear (fly cutting).
Fig. 8 is the stereographic map that utilizes the embodiment that min-cutter of the present invention cuts with rotate path.
Fig. 9 is existing cutter edge of a knife shape synoptic diagram in order to the making stereo microstructure.
Figure 10 to Figure 15 is the existing making schematic flow sheet of making the method for stereo microstructure with the optical etching method.
Embodiment
The present invention is for realizing above-mentioned and other purpose, and the technological means that it adopted, element and effect thereof adopt a preferred embodiment to cooperate correlative type to be described in detail as follows now.
Method of the present invention, it mainly is technology with photoetching mold (LIGA technology), produce a min-cutter in the electroforming mode, with the surface of this min-cutter, use the linear incision (fly cutting) or the mode of milling to go out a stereo microstructure then then at the shaping surface of machined object perpendicular to machined object.Because this min-cutter is to make formation with light die sinking mode, therefore its shape and size are the precision that depends on the little shadow of photoresistance fully, therefore make this min-cutter have the degree of accuracy of quite high size and shape, and the precision of the size and shape of its microstructure that processes is improved.
Manufacturing process of the present invention such as Fig. 1 are to shown in Figure 5, it mainly is to make a min-cutter with light die sinking mode earlier, as shown in Figure 1, on a planar substrates (Substratr) 10, coat earlier a crystal seed layer 11 (seed layer), and then coat photoresist (photoresist formation) 20 in the surface of crystal seed layer, then as Fig. 2 institute, mode with little shadow (lithography) is developed on photoresist 20, make photoresist 20 form a photoresistance pattern, constituting one can be in order to the photoetching mould 21 of the aforementioned min-cutter that is shaped.As shown in Figure 3, the shape of this photoetching mould 21 is identical with the flat shape of min-cutter, and its shape is the shape of the light shield (mask) that depends on use, so that the present invention can make the quite complicated min-cutter of shape, and make the precision of size and shape of cutter depend on the shape of light shield and the precision of size fully.
As shown in Figure 4, after the photoresistance pattern forms, can utilize electroforming (electroplating) method at this photoetching mould 21 internal shapings one min-cutter 30, electroforming material can be selected the composite material of nickel (Ni), Rhometal (NiFe), nickel cobalt (alloy) (NiCo), nickel tungsten (NiW) and nickel and carbonization silicon (SiC), the condition of its selection is that its physical characteristics can be shaped by electrocasting method, and must have suitable hardness, so that as cutting material.As shown in Figure 5, after electroforming is finished, this min-cutter 30 is taken off from electroformed mould, as shown in Figure 6, the shape of this min-cutter 30 is identical with the shape of aforementioned photoresistance pattern 21, and the precision of the size and shape of this min-cutter 30 is identical with the photoresistance pattern.
As shown in Figure 6, this min-cutter 30 has a cutting edge 31 that has corresponding geometric configuration with aforementioned stereo microstructure, therefore when using 30 pairs of machined objects of this min-cutter to carry out cut, this cutting edge 31 can be contacted with the surface of this machined object in orthogonal direction, and by this cutting edge 31 at machined object shaping surface one stereo microstructure.
As shown in Figures 7 and 8, after min-cutter 30 completes, it can be installed on the stock-removing machine, and then this min-cutter 30 is cut a stereo microstructure 41 on machined object 40.Embodiment as shown in Figure 7 is with after min-cutter 30 rotations one angle, is installed on the lathe tool rest 50, cuts stereo microstructure with linear cutting (fly cutting) mode on machined object 40 then.And embodiment as shown in Figure 8 then is that min-cutter 30 is set up on the tool rest 50, then cutter is cut out the stereo microstructure 42 of a concentric circles with rotation mode.
In sum, technological means of the present invention can have the advantage that the size and shape precision of stereo microstructure is made in chemical etching simultaneously, simultaneously can have the advantage quick and with low cost of machining process again, therefore it has the enhancement on the tangible effect really, and meets the condition of patent of invention really.
Claims (7)
1. a method of making stereo microstructure is characterized in that, comprises the following steps:
A. with the photoetching mould of method for photolithography making one in order to the forming tool of shaping stereo microstructure;
B. with the electrocasting method min-cutter that in this photoetching mould, is shaped;
C. this min-cutter is installed on the machining tool, and utilizes this min-cutter that one machined object is cut, the stereo microstructure that has corresponding shape in this machined object shaping surface one and this min-cutter.
2. the method for making stereo microstructure as claimed in claim 1 is characterized in that: this min-cutter cuts on this machined object with linear cutting way.
3. the method for making stereo microstructure as claimed in claim 1 is characterized in that: this min-cutter cuts on this machined object with rotation mode.
4. the method for making stereo microstructure as claimed in claim 1 is characterized in that: the material of this min-cutter is to select high hardness material.
5. the method for making stereo microstructure as claimed in claim 4 is characterized in that: high hardness material is nickel or Rhometal or nickel cobalt (alloy) or nickel tungsten or nickel and carbonization silicon synthetic material.
6. method in order to the min-cutter of making stereo microstructure, min-cutter has and the corresponding cutting edge shape of aforementioned stereo microstructure, it is characterized in that: this min-cutter has identical shaped photoetching mould by make one in little shadow mode on a planar substrates with this min-cutter, then with electroforming mode this min-cutter that is shaped in this photoetching mould.
7. the method in order to the min-cutter of making stereo microstructure as claimed in claim 6, it is characterized in that: the material of this min-cutter is to select high hardness material.
8. the method in order to the min-cutter of making stereo microstructure as claimed in claim 7, it is characterized in that: high hardness material is nickel or Rhometal or nickel cobalt (alloy) or nickel tungsten or nickel and carbonization silicon synthetic material.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CNB011042281A CN1178763C (en) | 2001-02-26 | 2001-02-26 | Method for making miniature cutter and stereo microstructure |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CNB011042281A CN1178763C (en) | 2001-02-26 | 2001-02-26 | Method for making miniature cutter and stereo microstructure |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| CN1371783A CN1371783A (en) | 2002-10-02 |
| CN1178763C true CN1178763C (en) | 2004-12-08 |
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CNB011042281A Expired - Fee Related CN1178763C (en) | 2001-02-26 | 2001-02-26 | Method for making miniature cutter and stereo microstructure |
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| CN (1) | CN1178763C (en) |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102172788A (en) * | 2011-01-13 | 2011-09-07 | 上海向隆电子科技有限公司 | Cutting tool, cutting tool module and manufacturing method of cutting tool |
Families Citing this family (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN106031955A (en) * | 2015-03-19 | 2016-10-19 | 苏州汉扬精密电子有限公司 | Electrode structure |
| CN110434403A (en) * | 2019-07-03 | 2019-11-12 | 福建夜光达科技股份有限公司 | High-efficiency and precision cuts the multitool mechanism and application method and application method of fine structure |
-
2001
- 2001-02-26 CN CNB011042281A patent/CN1178763C/en not_active Expired - Fee Related
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102172788A (en) * | 2011-01-13 | 2011-09-07 | 上海向隆电子科技有限公司 | Cutting tool, cutting tool module and manufacturing method of cutting tool |
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| Publication number | Publication date |
|---|---|
| CN1371783A (en) | 2002-10-02 |
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Granted publication date: 20041208 |