CN204188785U - A kind of xenon lamp of laser performance testing device - Google Patents
A kind of xenon lamp of laser performance testing device Download PDFInfo
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- CN204188785U CN204188785U CN201420668207.1U CN201420668207U CN204188785U CN 204188785 U CN204188785 U CN 204188785U CN 201420668207 U CN201420668207 U CN 201420668207U CN 204188785 U CN204188785 U CN 204188785U
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- xenon lamp
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- outgoing mirror
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Abstract
The utility model discloses a kind of xenon lamp of laser performance testing device, device comprises total reflective mirror, laser pump cavity and the outgoing mirror coaxially placed successively by optical path direction, and outgoing mirror side is also placed with for receiving and measuring the laser energy meter of laser energy; Working-laser material rod is placed with in laser pump cavity, population inversion is produced under working-laser material rod is used for the light stimulus sent at the xenon lamp being positioned at laser cavity, realize stimulated radiation light amplification, and self-sustained oscillation is realized further under the reflex of completely reflecting mirror and outgoing mirror, form the pulse laser with xenon lamp strong correlation, export through outgoing mirror.The device that the utility model proposes is by accessing lasing fluorescence light path by standard respectively with reference to pulse xenon lamp and survey xenon lamp to be measured, the emergent light energy of both contrasts, thus judge the performance change situation of xenon lamp to be measured, simply, safe, easy to operate, be applicable to laser pulse xenon lamp Performance Detection and maintenance.
Description
Technical field
The utility model relates to laser component Performance Detection field, more specifically, relates to a kind of xenon lamp of laser performance testing device.
Background technology
Pulse xenon lamp is important Parts in laser instrument and attrition component.Its performance directly affects the bright dipping energy/power of laser instrument, in order to ensure that laser instrument bright dipping energy/power meets certain threshold requirement, need change according to the cumulative operation time of pulse xenon lamp or hydraulic performance decline situation.But pulse xenon lamp running time is often difficult to know, and lack the method for direct-detection pulse xenon lamp performance change.
The method of existing detection laser pulse xenon lamp hydraulic performance decline has three kinds usually: (1) judges by observing the whether pitch-black and pitch-black degree of xenon lamp negative pole glass tube; (2) detect xenon lamp by vacuum test instrument whether to leak gas judgement; (3) go out luminous energy whether to decline judgement by measuring laser instrument.Wherein first method is to qualitatively judge, simple, intuitive but be difficult to rational judgment; Second method is a kind of determining method indirectly, directly perceived not and accuracy is not high; The situation of change that the third method can only go out luminous energy by laser instrument infers whether pulse xenon lamp performance declines, and due to laser instrument, to go out luminous energy not only relevant with pulse xenon lamp, therefore confidence level is not high.
A kind of test box of general ranging pulse xenon lamp electrical quantity is disclosed in Chinese utility model patent instructions CN201837643U, due to just ensureing that tester's safety is pressed and high voltage pulse with the lamp of test pulse xenon lamp under the condition of increasing work efficiency, the change of pulse xenon lamp performance can not be reacted directly and accurately.
Utility model content
For above defect or the Improvement requirement of prior art, the utility model provides a kind of laser pulse xenon lamp performance testing device, by standard is accessed lasing fluorescence light path respectively with reference to pulse xenon lamp and survey xenon lamp to be measured, the emergent light energy of both contrasts, thus judge the performance change situation of xenon lamp to be measured, simply, safe, easy to operate, the performance test that can be laser pulse xenon lamp with change part and repair a kind of effective method and foundation are provided.
The utility model solves the technical scheme that its technical matters adopts, a kind of xenon lamp of laser performance testing device is provided, described device comprises total reflective mirror, laser pump cavity and the outgoing mirror coaxially placed successively by optical path direction, and outgoing mirror side is also placed with for receiving and measuring the laser energy meter of laser energy; Laser pump cavity inside is placed with working-laser material rod, population inversion is produced under working-laser material rod is used for the light stimulus sent at the xenon lamp being positioned at laser pump cavity inside, realize stimulated radiation light amplification, and self-sustained oscillation is realized further under the reflex of completely reflecting mirror and outgoing mirror, form the pulse laser with xenon lamp strong correlation, export through outgoing mirror.
As further preferably, described total reflective mirror side is also placed with the internal focusing telescope for regulating each element coaxial of light path.
Therefore, the utility model can obtain following beneficial effect: the utility model builds the luminous light path of basic pulsed laser, by standard is accessed lasing fluorescence light path respectively with reference to pulse xenon lamp and survey xenon lamp to be measured, the emergent light energy of both contrasts, thus the performance change situation judging xenon lamp to be measured.The device that the utility model proposes is simple, safe, easy to operate, is applicable to laser pulse xenon lamp Performance Detection and maintenance.
Accompanying drawing explanation
Below in conjunction with drawings and Examples, the utility model is described in further detail, in accompanying drawing:
Fig. 1 is the utility model laser pulse xenon lamp performance testing device structural representation.
In figure: 1 completely reflecting mirror 2 xenon lamp 3 working-laser material rod 4 laser pump cavity 5 outgoing mirror 6 adjustment optical windows 7 detect optical window 8 internal focusing telescope 9 laser powermeter and to pop one's head in 10 laser powermeter main frame 11 detection cases
Embodiment
In order to make the purpose of this utility model, technical scheme and advantage clearly understand, below in conjunction with drawings and Examples, the utility model is further elaborated.Should be appreciated that specific embodiment described herein only in order to explain the utility model, and be not used in restriction the utility model.In addition, if below in described each embodiment of the utility model involved technical characteristic do not form conflict each other and just can mutually combine.
Measurement thinking of the present utility model is: build the luminous light path of basic pulsed laser, by standard is accessed lasing fluorescence light path respectively with reference to pulse xenon lamp and survey xenon lamp to be measured, the emergent light energy of both contrasts, thus the performance change situation judging xenon lamp to be measured.
First the luminous light path of basic pulsed laser is built.As shown in Figure 1, the luminous light path of basic pulsed laser comprises completely reflecting mirror 1, laser pump cavity 4, the outgoing mirror 5 placed successively, and be placed on xenon lamp 2 and the working-laser material rod 3 of laser pump cavity 4 inside, the position relationship of xenon lamp 2 and working-laser material rod 3, by the structures shape of laser pump cavity, is generally parallel placement.Such as when adopting the laser pump cavity of profile pump pattern, xenon lamp 2 mostly is parallel placement with working-laser material rod 3.For avoiding in testing process pulsed light to the injury of human eye, total reflective mirror, outgoing mirror, working-laser material rod, laser pump cavity and xenon lamp are placed in airtight detection case 11, and a viewing optics window 6 for adjustment and one are left respectively for receiving the detection optical window 7 of laser energy in the two ends of light path.Outside detection case, being placed with auxiliary water cooling plant for cooling xenon lamp and working-laser material rod in testing process, outside detection case, being placed with auxiliary xenon lamp power supply luminous for driving pulse xenon lamp.
For the ease of collimation and the alignment of each optical surface of the luminous light path of adjustment pulse laser generator, outside the adjustment optical window 6 of light path, place internal focusing telescope.
For the ease of the emanated energy of the luminous light path of ranging pulse laser instrument, have laser energy meter in detection window 7 arranged outside of light path, laser energy meter comprises laser powermeter probe 9 and laser power main frame 10.
In order to improve the accuracy of detection of pulse xenon lamp performance, the parts in the luminous light path of basic pulse laser instrument of structure can adopt the parts identical with type and construction in xenon lamp real work laser light path to be measured.
During the work of the utility model device, xenon lamp is loaded in laser pump cavity 4, fix the packoff at laser pump cavity two ends, luminous by external xenon lamp power supply driving pulse xenon lamp, xenon lamp converges at working-laser material rod after laser pump cavity reflection, active medium is wherein made to produce population inversion, realize stimulated radiation light amplification, self-sustained oscillation is realized further under the reflex of the resonator cavity formed at completely reflecting mirror 1 and outgoing mirror 5, form the pulse laser with xenon lamp strong correlation, laser energy meter is exported to through outgoing mirror 5, laser energy meter is measured and is read and the performance-relevant pulsed laser energy value of xenon lamp.
In Fig. 1, total reflective mirror 1, xenon lamp 2, working-laser material rod 3 (can be preferably YAG rod), laser pump cavity 4 and outgoing mirror 5 form basic lasing fluorescence light path, and wherein total reflective mirror 1 and outgoing mirror 5 form resonator cavity.Before test, first utilize internal focusing telescope 8 that each end face of total reflective mirror 1, working-laser material rod 3 and outgoing mirror 5 is adjusted to concentric co-axial; Connect water cooling plant then to laser pump cavity 4, pulse xenon lamp driving power is connected to xenon lamp 2, for convenience of using, water cooling plant water pipe is connected with laser pump cavity 4 by the fixed interface of detection case 11 side, and xenon lamp 2 is gone between and is also connected with pulse xenon lamp driving power by the fixed interface of detection case 11 side; Place laser powermeter probe 9 at detection window end, make laser powermeter probe 9 and light path coaxial, adjust laser powermeter main frame 10 parameter.For ease of regulating, basic luminous light path is adjusted to concentric co-axial, all light path elements are arranged on optics guide rail by adaptor and slide block, and the adaptor of total reflective mirror 1 and outgoing mirror 5 also possesses orientation and pitching rotatory power.
During test, first load in laser pump cavity 4 with reference to xenon lamp, generally select the new xenon lamp of high-quality with xenon lamp same model same specification to be measured with reference to xenon lamp, with reference to xenon lamp and the parallel placement of lasing material rod.Connect with reference to xenon lamp lead-in wire to detection case interface, then open with reference to xenon lamp driving power, water cooling plant is started working, arrange with reference to xenon lamp glow frequency (being generally no more than 10Hz) and make to start working with reference to xenon lamp, measure with reference to xenon lamp luminous energy by laser energy meter, record above-mentioned with reference to xenon lamp shoot laser energy P after displayed value is stable
0, for follow-up judgement with reference to xenon lamp performance.For with a collection of xenon lamp to be measured, only with measuring once with reference to the energy value of xenon lamp work.Then close xenon lamp driving power, change xenon lamp to be measured in laser pump cavity, xenon lamp to be measured and the parallel placement of lasing material rod, connect xenon lamp to be measured lead-in wire to detection case interface.When changing xenon lamp, careful operation is to avoid the alignment changing luminous light path, check whether alignment changes by interior focusing telescope after replacing completes, if change, fine setting total reflective mirror 1 and outgoing mirror 5, make each end face of total reflective mirror 1, working-laser material rod 3 and outgoing mirror 5 again keep coaxial.The each element of light path keeps coaxially again, open xenon lamp driving power to be measured, water cooling plant is started working, and makes xenon lamp to be measured and reference xenon lamp according to same frequency work, record and the performance-relevant xenon lamp shoot laser energy energy value P to be measured of xenon lamp to be measured after displayed value is stable
1.Obtain P
1/ P
0ratio Γ (Γ≤1), judge the decline degree of xenon lamp performance according to the large I of ratio Γ, Γ is less, judges that xenon lamp hydraulic performance decline to be measured is more.In conjunction with the requirement of laser instrument paired pulses xenon lamp performance, determine whether to need to change xenon lamp.
In test process, open airtight detection case upper cover for ease of operation; After having tested, cover detection case.
Those skilled in the art will readily understand; the foregoing is only preferred embodiment of the present utility model; not in order to limit the utility model; all do within spirit of the present utility model and principle any amendment, equivalent to replace and improvement etc., all should be included within protection domain of the present utility model.
Claims (2)
1. an xenon lamp of laser performance testing device, is characterized in that, described device comprises total reflective mirror, laser pump cavity and the outgoing mirror coaxially placed successively by optical path direction, and outgoing mirror side is also placed with for receiving and measuring the laser energy meter of laser energy; Laser pump cavity inside is placed with working-laser material rod, population inversion is produced under working-laser material rod is used for the light stimulus sent at the xenon lamp being positioned at laser pump cavity inside, realize stimulated radiation light amplification, and self-sustained oscillation is realized further under the reflex of completely reflecting mirror and outgoing mirror, form the pulse laser with xenon lamp strong correlation, export through outgoing mirror.
2. xenon lamp of laser performance testing device as claimed in claim 1, it is characterized in that, described total reflective mirror side is also placed with the internal focusing telescope for regulating each element coaxial of light path.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201420668207.1U CN204188785U (en) | 2014-11-10 | 2014-11-10 | A kind of xenon lamp of laser performance testing device |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201420668207.1U CN204188785U (en) | 2014-11-10 | 2014-11-10 | A kind of xenon lamp of laser performance testing device |
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| Publication Number | Publication Date |
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| CN204188785U true CN204188785U (en) | 2015-03-04 |
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201420668207.1U Expired - Fee Related CN204188785U (en) | 2014-11-10 | 2014-11-10 | A kind of xenon lamp of laser performance testing device |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104316887A (en) * | 2014-11-10 | 2015-01-28 | 中国人民解放军海军工程大学 | Performance test method and device for laser xenon lamp |
-
2014
- 2014-11-10 CN CN201420668207.1U patent/CN204188785U/en not_active Expired - Fee Related
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104316887A (en) * | 2014-11-10 | 2015-01-28 | 中国人民解放军海军工程大学 | Performance test method and device for laser xenon lamp |
| CN104316887B (en) * | 2014-11-10 | 2017-02-15 | 中国人民解放军海军工程大学 | Performance test method and device for laser xenon lamp |
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| Date | Code | Title | Description |
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| C14 | Grant of patent or utility model | ||
| GR01 | Patent grant | ||
| CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20150304 Termination date: 20171110 |
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| CF01 | Termination of patent right due to non-payment of annual fee |