CN201681210U - Quarter equal-proportion optical splitting appliance and laser reticle device with same - Google Patents
Quarter equal-proportion optical splitting appliance and laser reticle device with same Download PDFInfo
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- CN201681210U CN201681210U CN 201020128114 CN201020128114U CN201681210U CN 201681210 U CN201681210 U CN 201681210U CN 201020128114 CN201020128114 CN 201020128114 CN 201020128114 U CN201020128114 U CN 201020128114U CN 201681210 U CN201681210 U CN 201681210U
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- spectroscope
- focus lamp
- reflected light
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Abstract
The utility model discloses a quarter equal-proportion optical splitting appliance, which comprises a first reflector, a second reflector, a first spectroscope, a second spectroscope, a third spectroscope, a first focal lens, a second focal lens, a third focal lens and a fourth focal lens. The reflectance of both the first reflector and the second reflector is 100%; both the reflectance and the transmittance of the first spectroscope, the second spectroscope and the third spectroscope are 50%; and the first spectroscope, the third spectroscope and the first reflector are sequentially arranged on the same straight line of an incident collimated beam in a mutually parallel manner, the collimated beam forms a first beam, a second beam, a third beam and a fourth beam after passing through a quarter equal-proportion optical splitting system, and the power of all of the first beam, the second beam, the third beam and the fourth beam accounts for 25% of the power of the collimated beam. The quarter equal-proportion optical splitting appliance has the advantages of small number of optical elements, saved space and simultaneous reduction of optical energy loss. Additionally, the reflectance of all of the first spectroscope, the second spectroscope and the third spectroscope is 50%, the power of each of all the four beams eventually formed accounts for 25% of the energy of the collimated beam, and the quarter equal-proportion optical splitting appliance has even energy and favors reticle of lines with higher quality.
Description
Technical field
The utility model relates to optical field, relates in particular to a kind of four minutes equal proportion light-dividing devices and has the laser scoring equipment of this device.
Background technology
In the present solar battery laser groove technology, there is single laser instrument monochromatic light of employing road to process the technology that also has single laser instrument multi-pass to process.The light-splitting method that is divided into four tunnel cuttings such as a road common laser.
What but prior art was divided into that the light-splitting methods of four tunnel cuttings adopt to one road laser is the method for horizontal beam split or ratio beam split.
Horizontal light splitting technology: laser plane is horizontally disposed, the center of lens of element such as spectroscope, catoptron all is arranged on the same surface level, laser optical path is through repeatedly beam split, repeatedly still remain on and finish light transmission on the horizontal plane after the reflection, and it is 50%: 50% spectroscope that this method is only used the ratio of reflective power and transmission power usually.But this technology takies bigger surface level and arranges spectroscope and catoptron, and arrives focus lamp and want many primary events, and it is more and optical transmission loss is bigger to take light transmission component.
The ratio light splitting technology: laser is finished beam split on same straight line, and one minute four tunnel spectroscope reflective power and transmission power ratio were pressed 25%: 75%, 33%: 67%, 50%: 50% successively from the laser input direction, a last eyeglass reflectivity 100%.Though ratio light splitting technology conserve space, because of spectroscope reflective power and transmission power proportional jitter scope are bigger, each road luminous power is distributed and is had unbalanced phenomena.
At current situation, the utility model provides a kind of saving space, uniform four minutes equal proportion light-dividing devices of power division.
The utility model content
The purpose of this utility model is to provide a kind of saving space, four fens equal proportion light-dividing devices of power division equilibrium.
To achieve these goals, the technical solution of the utility model is: a kind of four minutes equal proportion light-dividing devices are provided, described four minutes equal proportion light-dividing devices are used for the collimated light beam of incident is carried out beam split, the equal proportion light-dividing device comprised reflector group, spectroscope group and focus lamp group in described four minutes, and described reflector group comprises that reflectivity is 100% first catoptron and second catoptron; Described spectroscope group comprises that reflectivity and transmissivity are 50% first spectroscope, second spectroscope and the 3rd spectroscope; Described focus lamp group comprises first focus lamp, second focus lamp, the 3rd focus lamp and the 4th focus lamp that focal length equates; On the same straight line at the collimated light beam place that places incident successively that described first spectroscope, the 3rd spectroscope, first catoptron are parallel to each other, described collimated light beam is to be incident to obliquely on described first spectroscope and forms first transmitted light and first reflected light, described first transmitted light is incident to and forms the 3rd transmitted light and the 3rd reflected light on the 3rd spectroscope, described the 3rd transmitted light is incident on first catoptron and forms the 4th reflected light, and described first reflected light, the 3rd reflected light and the 4th reflected light are parallel to each other and are positioned at the same side of collimated light beam; Described second spectroscope, the first catoptrical side that places corresponding first spectroscope of collimated light beam to be produced that second catoptron is parallel to each other, and described first reflected light is to be incident to obliquely on described second spectroscope and forms second transmitted light and second reflected light, described second reflected light is incident to the 5th reflected light that formation parallels with described second transmitted light on described second catoptron, described first focus lamp is located at and is formed the first bundle light on described the 5th reflected light, described second focus lamp is located at and is formed the second bundle light on described second transmitted light, described the 3rd focus lamp is located at and is formed three-beam on described the 3rd reflected light, and described the 4th focus lamp is located at and is formed the 4th bundle light on described the 4th reflected light.
Preferably, described second reflected light is parallel with collimated light beam.
Preferably, the center of described first focus lamp, second focus lamp, the 3rd focus lamp and the 4th focus lamp all is positioned on the straight line parallel with collimated light beam.
Preferably, distance between the light of the described first bundle light and second bundle, the second bundle light equate with the 4th distance of restrainting between the light with distance, three-beam between the three-beam.
The utility model also provides a kind of laser scoring equipment, comprise first platen, second platen, be fixed in laser instrument, beam expanding lens on described first platen, be slidingly connected to the some bases on described second platen, some described bases are provided with four fens equal proportion light-dividing devices, the equal proportion light-dividing device comprised reflector group in described four minutes, and described reflector group comprises that reflectivity is 100% first catoptron and second catoptron; Spectroscope group, described spectroscope group comprise that reflectivity and transmissivity are 50% first spectroscope, second spectroscope and the 3rd spectroscope; Focus lamp group, described focus lamp group comprise first focus lamp, second focus lamp, the 3rd focus lamp and the 4th focus lamp that focal length equates; On the same straight line at the collimated light beam place that places incident successively that described first spectroscope, the 3rd spectroscope, first catoptron are parallel to each other, described collimated light beam is to be incident to obliquely on described first spectroscope and forms first transmitted light and first reflected light, described first transmitted light is incident to and forms the 3rd transmitted light and the 3rd reflected light on the 3rd spectroscope, described the 3rd transmitted light is incident on first catoptron and forms the 4th reflected light, and described first reflected light, the 3rd reflected light and the 4th reflected light are parallel to each other and are positioned at the same side of collimated light beam; Described second spectroscope, the first catoptrical side that places corresponding first spectroscope of collimated light beam to be produced that second catoptron is parallel to each other, and described first reflected light is to be incident to obliquely on described second spectroscope and forms second transmitted light and second reflected light, described second reflected light is incident to the 5th reflected light that formation parallels with described second transmitted light on described second catoptron, described first focus lamp is located at and is formed the first bundle light on described the 5th reflected light, described second focus lamp is located at and is formed the second bundle light on described second transmitted light, described the 3rd focus lamp is located at and is formed three-beam on described the 3rd reflected light, and described the 4th focus lamp is located at and is formed the 4th bundle light on described the 4th reflected light.
Preferably, this laser scoring equipment also comprises the horizontal shifting platform that is fixedly arranged on described second platen, and described base along continuous straight runs on described horizontal shifting platform is free to slide.
Preferably, described base has cutting head, and described cutting head comprises focus lamp and nozzle, also is provided with the vertical moving platform of regulating defocusing amount and described nozzle height on the described base.
Preferably, described vertical moving platform comprises coarse adjustment vertical moving platform and accurate adjustment vertical moving platform, thereby described coarse adjustment vertical moving platform swivel nozzle is regulated the height of described nozzle, thus height and defocusing amount that the height of the described cutting head of described accurate adjustment vertical moving platform accurate adjustment is regulated described nozzle.
Compared with prior art, the optical element of this four fens equal proportion light-dividing devices is few, and conserve space also reduces the loss of luminous energy; This first spectroscope, second spectroscope, the 3rd spectroscopical reflectivity are 50%, form the light that four beam powers all account for collimated light beam energy 25% at last, and energy even helps depicting higher-quality lines.
By following description also in conjunction with the accompanying drawings, it is more clear that the utility model will become, and these accompanying drawings are used to explain embodiment of the present utility model.
Description of drawings
Fig. 1 is the structural arrangement synoptic diagram of the utility model laser scoring equipment
Fig. 2 is the light path principle figure of four fens equal proportion light-dividing devices of laser scoring equipment shown in Figure 1
Embodiment
Fig. 1 is the structural arrangement synoptic diagram that the utlity model has the laser scoring equipment of four fens equal proportion light-dividing devices.As shown in Figure 1, the utility model laser scoring equipment 1000 comprises first platen 100, second platen 200, is fixed in laser instrument 300, beam expanding lens 400, catoptron 500,600 on described first platen 100, is slidingly connected to the some bases on described second platen 200.In the present embodiment, base adopts the 6061A aluminium alloy to process, and has good corrosion resistivity and weldability.
The preferably, coarse adjustment vertical moving platform is regulated the scope of height between 100 millimeters to 200 millimeters; Accurate adjustment vertical moving platform is regulated the scope of height between 20 millimeters to 30 millimeters.
Particularly, in conjunction with Fig. 1 and Fig. 2, base comprises first base 10, second base 20, the 3rd base 30 and the 4th base 40.The top of the vertical core of first base, 10 correspondences is provided with second catoptron 11.Second base 20 is provided with first spectroscope 21 and is positioned at second spectroscope, 22, the first spectroscopes 21 directly over first spectroscope 21 over against the vertical core of first base 10.Second spectroscope 22 and second catoptron 11 are parallel to each other.The 3rd base 30 is provided with the 3rd spectroscope 31, the four bases 40 and is provided with first catoptron 41.Second spectroscope 22, the 3rd spectroscope 31 and first catoptron 41 are located along the same line.Place, the center straight line of second spectroscope 22 and second catoptron 41 and second spectroscope 22, the 3rd spectroscope 31 and place, first catoptron, 41 center straight line are parallel to each other.The reflectivity of second catoptron 11, first catoptron 41 is that the reflectivity of 100%, the first spectroscope 21, second spectroscope 22, spectroscope 31 is 50%.First focus lamp 12, second focus lamp 23, the 3rd focus lamp 32, the 4th focus lamp 42 are respectively the focus lamp of first base 10, second base 20, the 3rd base 30, the 4th base 40 correspondences, lay respectively at second catoptron 11, second spectroscope 22, the 3rd spectroscope 31, first catoptron 41 directly over.Place, center straight line and second spectroscope 22, the 3rd spectroscope 31 and first catoptron, the 41 place straight lines of first focus lamp 12, second focus lamp 23, the 3rd focus lamp 32, the 4th focus lamp 42 are parallel to each other.First focus lamp 12, second focus lamp 23, the 3rd focus lamp 32, the 4th focus lamp 42 form four fens equal proportion light-dividing devices together with second catoptron 11, first catoptron 41, first spectroscope, second spectroscope 22, the 3rd spectroscope 31.
The transmission of same light between second catoptron 11, first catoptron 41, first spectroscope 21, second spectroscope 22, the 3rd spectroscope 31 and the focus lamp of four fens equal proportion light-dividing devices of the utility model all is positioned on the same vertical plane, thereby saved the space; The optical element of this four fens equal proportion light-dividing devices is few, and conserve space reduces the loss of luminous energy simultaneously; The reflectivity of this first spectroscope 21, second spectroscope 22, the 3rd spectroscope 31 is 50%, forms the light that four beam powers all account for collimated light beam energy 25% at last, and energy even helps depicting higher-quality lines.
It should be noted that four fens equal proportion light-dividing devices of the utility model are not limited to one minute four tunnel beam splitting system, also can be one-to-two road beam splitting system or one minute eight tunnel beam splitting system, as long as suitably adjust the quantity of catoptron, spectroscope and focus lamp.
Abovely the utility model is described, but the utility model is not limited to the embodiment of above announcement, and should contains various modification, equivalent combinations of carrying out according to the essence of present embodiment in conjunction with most preferred embodiment.
Claims (11)
1. four fens equal proportion light-dividing devices are used for the collimated light beam of incident is carried out beam split, it is characterized in that, comprising:
Reflector group, described reflector group comprise that reflectivity is 100% first catoptron and second catoptron;
Spectroscope group, described spectroscope group comprise that reflectivity and transmissivity are 50% first spectroscope, second spectroscope and the 3rd spectroscope;
Focus lamp group, described focus lamp group comprise first focus lamp, second focus lamp, the 3rd focus lamp and the 4th focus lamp that focal length equates;
On the same straight line at the collimated light beam place that places incident successively that described first spectroscope, the 3rd spectroscope, first catoptron are parallel to each other, described collimated light beam is to be incident to obliquely on described first spectroscope and forms first transmitted light and first reflected light, described first transmitted light is incident to and forms the 3rd transmitted light and the 3rd reflected light on the 3rd spectroscope, described the 3rd transmitted light is incident on first catoptron and forms the 4th reflected light, and described first reflected light, the 3rd reflected light and the 4th reflected light are parallel to each other and are positioned at the same side of collimated light beam;
Described second spectroscope, second catoptron, first a catoptrical side that places corresponding first spectroscope of collimated light beam to be produced parallel to each other, and described first reflected light is to be incident to obliquely on described second spectroscope and forms second transmitted light and second reflected light, and described second reflected light is incident to the 5th reflected light that formation parallels with described second transmitted light on described second catoptron;
Described first focus lamp is located at and is formed the first bundle light on described the 5th reflected light, described second focus lamp is located at and is formed the second bundle light on described second transmitted light, described the 3rd focus lamp is located at and is formed three-beam on described the 3rd reflected light, and described the 4th focus lamp is located at and is formed the 4th bundle light on described the 4th reflected light.
2. four minutes as claimed in claim 1 equal proportion light-dividing devices is characterized in that: described second reflected light is parallel with collimated light beam.
3. four minutes as claimed in claim 1 equal proportion light-dividing devices is characterized in that: the center of described first focus lamp, second focus lamp, the 3rd focus lamp and the 4th focus lamp all is positioned on the straight line parallel with collimated light beam.
4. four minutes as claimed in claim 1 equal proportion light-dividing devices is characterized in that: distance between the light of the described first bundle light and second bundle, the second bundle light equate with the 4th distance of restrainting between the light with distance, three-beam between the three-beam.
5. laser scoring equipment, comprise first platen, second platen, be fixed in laser instrument, beam expanding lens on described first platen, be slidingly connected to the some bases on described second platen, some described bases are provided with four fens equal proportion light-dividing devices, it is characterized in that: the equal proportion light-dividing device comprised in described four minutes:
Reflector group, described reflector group comprise that reflectivity is 100% first catoptron and second catoptron;
Spectroscope group, described spectroscope group comprise that reflectivity and transmissivity are 50% first spectroscope, second spectroscope and the 3rd spectroscope;
Focus lamp group, described focus lamp group comprise first focus lamp, second focus lamp, the 3rd focus lamp and the 4th focus lamp that focal length equates;
On the same straight line at the collimated light beam place that places incident successively that described first spectroscope, the 3rd spectroscope, first catoptron are parallel to each other, described collimated light beam is to be incident to obliquely on described first spectroscope and forms first transmitted light and first reflected light, described first transmitted light is incident to and forms the 3rd transmitted light and the 3rd reflected light on the 3rd spectroscope, described the 3rd transmitted light is incident on first catoptron and forms the 4th reflected light, and described first reflected light, the 3rd reflected light and the 4th reflected light are parallel to each other and are positioned at the same side of collimated light beam;
Described second spectroscope, second catoptron, first a catoptrical side that places corresponding first spectroscope of collimated light beam to be produced parallel to each other, and described first reflected light is to be incident to obliquely on described second spectroscope and forms second transmitted light and second reflected light, and described second reflected light is incident to the 5th reflected light that formation parallels with described second transmitted light on described second catoptron;
Described first focus lamp is located at and is formed the first bundle light on described the 5th reflected light, described second focus lamp is located at and is formed the second bundle light on described second transmitted light, described the 3rd focus lamp is located at and is formed three-beam on described the 3rd reflected light, and described the 4th focus lamp is located at and is formed the 4th bundle light on described the 4th reflected light.
6. laser scoring equipment as claimed in claim 5 is characterized in that: described second reflected light is parallel with collimated light beam.
7. laser scoring equipment as claimed in claim 5 is characterized in that: the center of described first focus lamp, second focus lamp, the 3rd focus lamp and the 4th focus lamp all is positioned on the straight line parallel with collimated light beam.
8. laser scoring equipment as claimed in claim 5 is characterized in that: distance between the light of the described first bundle light and second bundle, the second bundle light equate with the 4th distance of restrainting between the light with distance, three-beam between the three-beam.
9. laser scoring equipment as claimed in claim 5 is characterized in that: also comprise the horizontal shifting platform that is fixedly arranged on described second platen, described base along continuous straight runs on described horizontal shifting platform is free to slide.
10. laser scoring equipment as claimed in claim 5 is characterized in that: described base has cutting head, and described cutting head comprises focus lamp and nozzle, also is provided with the vertical moving platform of regulating defocusing amount and described nozzle height on the described base.
11. laser scoring equipment as claimed in claim 10, it is characterized in that: described vertical moving platform comprises coarse adjustment vertical moving platform and accurate adjustment vertical moving platform, thereby described coarse adjustment vertical moving platform swivel nozzle is regulated the height of described nozzle, thus height and defocusing amount that the height of the described cutting head of described accurate adjustment vertical moving platform accurate adjustment is regulated described nozzle.
Priority Applications (1)
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CN 201020128114 CN201681210U (en) | 2010-03-05 | 2010-03-05 | Quarter equal-proportion optical splitting appliance and laser reticle device with same |
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CN 201020128114 CN201681210U (en) | 2010-03-05 | 2010-03-05 | Quarter equal-proportion optical splitting appliance and laser reticle device with same |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101923219A (en) * | 2010-03-05 | 2010-12-22 | 东莞宏威数码机械有限公司 | Quartering equal-proportion light-splitting device and laser marking machine with same |
CN103433620A (en) * | 2013-09-05 | 2013-12-11 | 深圳市大族激光科技股份有限公司 | Laser cutting device and light splitting assembly thereof |
CN107824975A (en) * | 2017-09-26 | 2018-03-23 | 丹阳东激光技术有限公司 | A kind of multiple head laser coder based on energy light splitting technology |
-
2010
- 2010-03-05 CN CN 201020128114 patent/CN201681210U/en not_active Expired - Lifetime
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101923219A (en) * | 2010-03-05 | 2010-12-22 | 东莞宏威数码机械有限公司 | Quartering equal-proportion light-splitting device and laser marking machine with same |
CN101923219B (en) * | 2010-03-05 | 2012-02-01 | 东莞宏威数码机械有限公司 | Quartering equal-proportion light-splitting device and laser marking machine with same |
CN103433620A (en) * | 2013-09-05 | 2013-12-11 | 深圳市大族激光科技股份有限公司 | Laser cutting device and light splitting assembly thereof |
CN103433620B (en) * | 2013-09-05 | 2016-08-17 | 大族激光科技产业集团股份有限公司 | Laser cutting device and spectrum groupware thereof |
CN107824975A (en) * | 2017-09-26 | 2018-03-23 | 丹阳东激光技术有限公司 | A kind of multiple head laser coder based on energy light splitting technology |
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Legal Events
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
AV01 | Patent right actively abandoned |
Granted publication date: 20101222 Effective date of abandoning: 20120201 |