CN205942076U - Rotatory light path of microscope objective - Google Patents
Rotatory light path of microscope objective Download PDFInfo
- Publication number
- CN205942076U CN205942076U CN201620797502.6U CN201620797502U CN205942076U CN 205942076 U CN205942076 U CN 205942076U CN 201620797502 U CN201620797502 U CN 201620797502U CN 205942076 U CN205942076 U CN 205942076U
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- microscope
- outfan
- rotation
- relay lenss
- lens
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Abstract
The utility model provides a light path can keep its optical distance not change when objective are rotatory, and microscopical other light paths need not to make corresponding adjustment that rotatory light path of microscope objective especially realizes through the formation of image trunking scheme that the microscope objective can use the focus to realize as the center that multi freedom is rotatory for one kind. It includes objective interface adapter, first swivel mount, first right angle optical adjustment frame, second swivel mount, a relay lens, second right angle optical adjustment frame, third right angle optical adjustment frame, the 2nd relay lens and cage form cube. The utility model discloses simple structure, with low costs, rotation angle is big, can use with the whole audience or scanning microscope collocation.
Description
Technical field
This utility model is related to a kind of microscope objective rotation light path, particularly a kind of aobvious by being imaged trunking scheme realization
Objective can realize the light path of multiple degrees of freedom rotation centered on focus, and its light path can be kept not send out in lens rotation
Changing, other light paths microscopical need not make corresponding adjustment.
Background technology
In recent years the demand of living body biological sample imaging is led to the fast development of multiple micro-imaging techniques, wherein
Including whole audience imaging and flying spot(Flying Spot)Scanning imagery two big class.Whole audience imaging includes whole-field optically coherent tomography
Picture(Full Field Optical Coherence Tomography)Deng;Scanning imagery includes Excited Fluorescence Combined
(Multiphoton Excited Fluorescence), secondary/triple-frequency harmonics generation (Second/Third Harmonic
Generation), stimulated Raman scattering (Stimulated Raman Scattering), coherent anti-stokes raman scattering
Imaging such as (Coherent Anti-stokes Raman Scattering) nonlinear optics etc..(Modal whole audience fluorescence shows
Micro mirror and laser confocal scanning microscope are used for biological sample due to wavelength reason, but are rarely used in living body biological sample,
Therefore equally can be had little significance using the still practical application that designs of the present utility model.)Simple microscope, no matter just putting or
It is inverted, being generally fixed for as light path and horizontal plane is that sample place plane is vertical.Sample is generally also thin slice.But for live body
For biological sample imaging, the profile of living body biological has concrete 3D shape, and surface is nonplanar, is imaged position
Varied:Sometimes, when object lens are vertical with imaging surface, living body biological is askew;Sometimes, during living body biological horizontal, object lens are just no
Method is vertical with imaging surface, leads to the microscope cannot normal work.So the fixed imaging light path of simple microscope is difficult to meet
The requirement of living body biological sample imaging.
Living body biological sample imaging need one kind realize microscope objective can be realized centered on focus multiple degrees of freedom rotation
The light path turning, so in lens rotation, without adjusting position, and object lens need not focus on sample repeatedly.Additionally, this rotation light
Road can keep its light path not change in lens rotation.Because for whole-field optically coherent fault imaging, if
Positioned at sample arm(Sample Arm)Rotation light path in lens rotation its light path change, then reference arm light path need
Make corresponding adjustment(For Time Domain Optical coherence tomography);For scanning microscope, if rotation light path is in object lens
During rotation, its light path changes means that the light path between sleeve lens and object lens changes, then scanning lenses and probe
Between light path accordingly adjust.And in this microscope, other light paths will make corresponding adjustment while lens rotation is very
Difficult.In commercial microscope product, the Bergamo II of only Thorlabs company of the U.S. enables similar functions at present, but
The anglec of rotation is limited(0 degree to 95 degree).
Therefore the utility model proposes a kind of microscope objective rotation light path, particularly one kind is by being imaged trunking scheme
Realize the light path that microscope objective can realize multiple degrees of freedom rotation centered on focus.This utility model energy in lens rotation
Its light path is enough kept not change, other light paths microscopical need not make corresponding adjustment.This utility model has structure letter
Single, low cost and other advantages are it is adaptable to be used for the various whole audience/scanning microscopes of living body biological sample imaging.
Content of the invention
The purpose of this utility model is to realize a kind of microscope objective rotation light path, and particularly one kind is by being imaged relaying side
Formula realizes the light path that microscope objective can realize multiple degrees of freedom rotation centered on focus, can keep it in lens rotation
Light path does not change, and other light paths microscopical need not make corresponding adjustment.
For achieving the above object, this utility model using technical scheme is:It includes object lens interface adapter, the first rotation
Frame, the first right optical adjustment frame, the second swivel mount, the first relay lenss, the second right optical adjustment frame, the 3rd right optical
Adjustment frame, the second relay lenss, caged cube, the input of object lens interface adapter and outside microscopical microscope adapter
Connect, the outfan of object lens interface adapter is connected with the input of the first swivel mount, the outfan of the first swivel mount and first
The input of right optical adjustment frame connects, and the input of the outfan of the first right optical adjustment frame and the second swivel mount is even
Connect, the outfan of the second swivel mount is connected with the input of the first relay lenss, the outfan of the first relay lenss is straight with second
Input connection, the outfan of the second right optical adjustment frame and the input of the 3rd right optical adjustment frame of angle optical adjusting frame
End connects, and the outfan of the 3rd right optical adjustment frame is connected with the input of the second relay lenss, the second relay lenss defeated
Go out and hold input cubical with caged to be connected, detect when this utility model is used for NDD(Non-Descaned Detector)
When, caged cube is dichroic mirror and optical filter, the cubical outfan of caged and external objective lens or its adapter in vivo
Connect, another outfan with outside photoelectricity testing part or light-guide device be connected, the output of outside photoelectric detector with micro-
Mirror is connected, and light-guide device photoelectricity testing part original with microscope is connected, when this utility model is not used in NDD detection, cage
Shape cube is reflecting mirror in vivo, and the cubical outfan of caged is connected with external objective lens or its adapter.
Described object lens interface adapter be used for by various object lens use external screw thread be converted to standard thread and with micro-
Mirror is connected;
The first described swivel mount is used for realizing 360 degree of rotations, and rotation mode for continuous or stepping, type of drive can be able to be
Manually or electrically, and there is locking device make it fixing at an arbitrary position;
The first described right optical adjustment frame is used for realizing installing reflecting mirror by 90 degree of Beam rotation, and reflecting mirror can be
Any materials as needed, wavelength, the reflecting mirror of shape;
The second described swivel mount is used for realizing 360 degree of rotations, and rotation mode for continuous or stepping, type of drive can be able to be
Manually or electrically, and there is locking device make it fixing at an arbitrary position;
The first described relay lenss are parallel for being converted to the angle scanning collimated beam of microscope inner sleeve lens
Focus on light beam, the front focus of the first relay lenss is located at the rear focal point of microscope inner sleeve lens, and the first relay lenss are permissible
It is according to any materials, wavelength, shape, the lens of focal length or the lens combination needing;
The second described right optical adjustment frame is used for realizing installing reflecting mirror by 90 degree of Beam rotation, and reflecting mirror can be
Any materials as needed, wavelength, the reflecting mirror of shape;
The 3rd described right optical adjustment frame is used for realizing installing reflecting mirror by 90 degree of Beam rotation, and reflecting mirror can be
Any materials as needed, wavelength, the reflecting mirror of shape;
The second described relay lenss are parallel for being converted to the angle scanning collimated beam of microscope inner sleeve lens
Focus on light beam, the front focus of the second relay lenss is located at the rear focal point of microscope inner sleeve lens, and the second relay lenss are permissible
It is according to any materials, wavelength, shape, the lens of focal length or the lens combination needing;
Described caged cube is used for accommodating different optical elements, detects when this utility model is used for NDD(It is common in
Excited Fluorescence Combined, secondary/triple-frequency harmonics occurs, stimulated Raman scattering, and coherent anti-stokes raman scattering etc. is non-linear
Optical imagery)When, caged cube is in vivo dichroic mirror and optical filter, the cubical outfan of caged and external objective lens or
Its adapter connect, another outfan with outside photoelectricity testing part or light-guide device be connected, outside photoelectric detector defeated
Go out and be connected with microscope, light-guide device photoelectricity testing part original with microscope is connected, when this utility model is not used in NDD inspection
Survey(It is common in whole audience microscope and confocal scanning microscope etc.)When, caged cube is reflecting mirror in vivo, and caged is cubical
Outfan is connected with external objective lens or its adapter;
Operation principle of the present utility model is such:When using, the input of object lens interface adapter is shown with outside
The microscope adapter of micro mirror connects, and the outfan of object lens interface adapter is connected with the input of the first swivel mount, the first rotation
The outfan of frame is connected with the input of the first right optical adjustment frame, and the outfan of the first right optical adjustment frame and second revolves
The input of pivoted frame connects, and the outfan of the second swivel mount is connected with the input of the first relay lenss, the first relay lenss
Outfan is connected with the input of the second right optical adjustment frame, the outfan of the second right optical adjustment frame and the 3rd right angle light
The input learning adjustment frame connects, and the outfan of the 3rd right optical adjustment frame is connected with the input of the second relay lenss, the
The outfan of two relay lenss input cubical with caged is connected, when this utility model is used for NDD detection, caged cube
It is dichroic mirror and optical filter in vivo, the cubical outfan of caged is connected with external objective lens or its adapter, another
Outfan is connected with outside photoelectricity testing part or light-guide device, and the output of outside photoelectric detector is connected with microscope, guide-lighting
Element photoelectricity testing part original with microscope is connected, and when this utility model is not used in NDD detection, caged cube is in vivo
Reflecting mirror, the cubical outfan of caged is connected with external objective lens or its adapter.Microscopical scanning lenses are anti-by probe
The angle scanning collimated beam penetrated is imaged on its front focal plane, and is converted to angle scanning collimated beam by sleeve lens and converges in
Thereafter after in focus through the first relay lenss imaging behind on focal plane, after be converted to angle for the second time through the second relay lenss
Degree scanning collimated beam converges focus enter object lens behind.This utility model can be with the first swivel mount with microscopical one-tenth
Horizontal optical axis as optical axis carries out 360 degree of rotations for rotary shaft, after being ratated 90 degrees with first time with the second swivel mount simultaneously
Carry out 360 degree of rotations for rotary shaft.Object focal point is located on horizon light axle it is meant that object lens can be realized centered on focus
The light path of multiple degrees of freedom rotation, can keep its light path not change, other light paths microscopical need not in lens rotation
Make corresponding adjustment.Compare original microscope, this utility model introduces multi-disc reflecting mirror, relay lenss and other optics unit
Part, can make ultrashort laser pulse broadening, produce impact it is therefore desirable to make extra dispersion compensation to nonlinear imaging application.
This utility model, due to employing technique scheme, has the advantage that:
1st, object lens can realize multiple degrees of freedom rotation centered on focus, and sample need not adjust, and object lens need not focus on repeatedly,
Other light paths microscopical need not make corresponding adjustment;
2nd, structure is simple, low cost;
3rd, can use with the whole audience or scanning microscope collocation.
Brief description
Fig. 1 is structured flowchart of the present utility model.
Specific embodiment
The utility model is described in further detail with reference to the accompanying drawings and examples:As shown in figure 1, it includes object lens interface
Adapter 1, the first swivel mount 2, the first right optical adjustment frame 3, the second swivel mount 4, the first relay lenss 5, the second right angle light
Learn adjustment frame 6, the 3rd right optical adjustment frame 7, the second relay lenss 8, caged cube 9, the input of object lens interface adapter
End is connected with outside microscopical microscope adapter, and the input of the outfan of object lens interface adapter 1 and the first swivel mount 2 is even
Connect, the outfan of the first swivel mount 2 is connected with the input of the first right optical adjustment frame 3, the first right optical adjustment frame 3
Outfan is connected with the input of the second swivel mount 4, and the input of the outfan of the second swivel mount 4 and the first relay lenss 5 is even
Connect, the outfan of the first relay lenss 5 is connected with the input of the second right optical adjustment frame 6, the second right optical adjustment frame 6
Outfan be connected with the input of the 3rd right optical adjustment frame 7, in the outfan and second of the 3rd right optical adjustment frame 7
The input of lens 8 of continuing connects, and the outfan of the second relay lenss 8 is connected with the input of caged cube 9, when this practicality newly
When type detects for NDD, it is dichroic mirror and optical filter, an outfan of caged cube 9 and outside in caged cube 9
Object lens or its adapter connect, and another outfan is connected with outside photoelectricity testing part or light-guide device, outside Photoelectric Detection
The output of device is connected with microscope, and light-guide device photoelectricity testing part original with microscope is connected, when this utility model without
When NDD detects, it is reflecting mirror in caged cube 9, the outfan of caged cube 9 is connected with external objective lens or its adapter
Connect.
Described object lens interface adapter 1 be used for by various object lens use external screw thread be converted to standard thread and with micro-
Mirror is connected;
The first described swivel mount 2 is used for realizing 360 degree of rotations, and rotation mode can be continuous or stepping, and type of drive can
For manually or electrically, and there is locking device make it fixing at an arbitrary position;
Described first right optical adjustment frame 3 is used for realizing installing reflecting mirror by 90 degree of Beam rotation,
Reflecting mirror can be according to any materials needing, wavelength, the reflecting mirror of shape;
The second described swivel mount 4 is used for realizing 360 degree of rotations, and rotation mode can be continuous or stepping, and type of drive can
For manually or electrically, and there is locking device make it fixing at an arbitrary position;
The first described relay lenss 5 are parallel for being converted to the angle scanning collimated beam of microscope inner sleeve lens
Focus on light beam, the front focus of the first relay lenss 5 is located at the rear focal point of microscope inner sleeve lens, and the first relay lenss 5 can
Think any materials as needed, wavelength, shape, the lens of focal length or lens combination;
Described second right optical adjustment frame 6 is used for realizing installing reflecting mirror by 90 degree of Beam rotation, and reflecting mirror is permissible
It is according to any materials needing, wavelength, the reflecting mirror of shape;
Described 3rd right optical adjustment frame 7 is used for realizing installing reflecting mirror by 90 degree of Beam rotation, and reflecting mirror is permissible
It is according to any materials needing, wavelength, the reflecting mirror of shape;
The second described relay lenss 8 are parallel for being converted to the angle scanning collimated beam of microscope inner sleeve lens
Focus on light beam, the front focus of the second relay lenss 8 is located at the rear focal point of microscope inner sleeve lens, and the second relay lenss 8 can
Think any materials as needed, wavelength, the lens of shape or lens combination;
Described caged cube 9 is used for accommodating different optical elements, detects when this utility model is used for NDD(Common
In Excited Fluorescence Combined, secondary/triple-frequency harmonics occurs, stimulated Raman scattering, the non-thread such as coherent anti-stokes raman scattering
Property optical imagery)When, it is dichroic mirror and optical filter in caged cube 9, an outfan of caged cube 9 and outside thing
Mirror or its adapter connect, and another outfan is connected with outside photoelectricity testing part or light-guide device, outside photoelectric detector
Output be connected with microscope, light-guide device photoelectricity testing part original with microscope is connected, when this utility model is not used in
NDD detects(It is common in whole audience microscope and confocal scanning microscope etc.)When, it is reflecting mirror in caged cube 9, caged is stood
The outfan of cube 9 is connected with external objective lens or its adapter;
Operation principle of the present utility model is such:When using, the input of object lens interface adapter 1 is shown with outside
The microscope adapter of micro mirror connects, and the outfan of object lens interface adapter 1 is connected with the input of the first swivel mount 2, the first rotation
The outfan of pivoted frame 2 is connected with the input of the first right optical adjustment frame 3, the outfan of the first right optical adjustment frame 3 with
The input of the second swivel mount 4 connects, and the outfan of the second swivel mount 4 is connected with the input of the first relay lenss 5, in first
The outfan of lens 5 of continuing is connected with the input of the second right optical adjustment frame 6, the outfan of the second right optical adjustment frame 6
It is connected with the input of the 3rd right optical adjustment frame 7, the outfan of the 3rd right optical adjustment frame 7 and the second relay lenss 8
Input connect, the outfan of the second relay lenss 8 is connected with the input of caged cube 9, when this utility model is used for
During NDD detection, be dichroic mirror and optical filter in caged cube 9, an outfan of caged cube 9 and external objective lens or
Its adapter connect, another outfan with outside photoelectricity testing part or light-guide device be connected, outside photoelectric detector defeated
Go out and be connected with microscope, light-guide device photoelectricity testing part original with microscope is connected, when this utility model is not used in NDD inspection
During survey, it is reflecting mirror in caged cube 9, an outfan of caged cube 9 is connected with external objective lens or its adapter.Aobvious
The angle scanning collimated beam that probe reflects is imaged on its front focal plane the scanning lenses of micro mirror, and is changed by sleeve lens
Be imaged behind on focal plane through the first relay lenss 5 after converging behind in focus for angle scanning collimated beam, after warp
Second relay lenss 8 are converted to angle scanning collimated beam for second and converge focus enter object lens behind.This utility model
With the first swivel mount 2,360 degree of rotations can be carried out for rotary shaft with microscopical imaging optical axis, the second swivel mount can be used simultaneously
The 4 horizontal optical axises after to ratate 90 degrees for the first time carry out 360 degree of rotations for rotary shaft.Object focal point is located on horizon light axle,
Mean that object lens can realize the light path of multiple degrees of freedom rotation centered on focus, its light path can be kept not in lens rotation
Change, other light paths microscopical need not make corresponding adjustment.Compare original microscope, this utility model introduces multi-disc
Reflecting mirror, relay lenss and other optical elements, can make ultrashort laser pulse broadening, produce impact to nonlinear imaging application,
It is thus desirable to making extra dispersion compensation.
The material of described object lens interface adapter 1 can be any materials processed with any technique according to demand;
The first described swivel mount 2 and the second swivel mount 4 are used for realizing 360 degree of rotations, and rotation mode can be continuous or step
Entering, type of drive can be manually or electrically, and have locking device makes it fixing at an arbitrary position;
The first described right optical adjustment frame 3 and the second right optical adjustment frame 6 and the 3rd right optical adjustment frame 7 can
Think any materials as needed, wavelength, the reflecting mirror of shape;
The first described relay lenss 5 and the second relay lenss 8 can be the wavelength according to any materials needing, shape,
The lens of focal length or lens combination;
Described caged cube 9 is used for accommodating different optical elements, when this utility model is used for NDD detection, cage
It is dichroic mirror and optical filter in shape cube 9, an outfan of caged cube 9 is connected with external objective lens or its adapter
Connect, another outfan is connected with outside photoelectricity testing part or light-guide device, the output of outside photoelectric detector and microscope
It is connected, light-guide device photoelectricity testing part original with microscope is connected, when this utility model is not used in NDD detection, caged
It is reflecting mirror in cube 9, the outfan of caged cube 9 is connected with external objective lens or its adapter.
The first described relay lenss and the second relay lenss are achromatism structure or apochromatism structure.
The surface of the first described relay lenss and the second relay lenss is coated with high permeability thin film.
The transmission wavelength of the first described relay lenss and the second relay lenss is 100nm to 2um.
The surface of described reflecting mirror is coated with high permeability thin film.
The transmission wavelength of described reflecting mirror is 100nm to 2um.
The described rotary shaft of the first swivel mount and microscopical imaging optical axis coincidence.
The rotary shaft of the second described swivel mount is through the focus of object lens.
The anglec of rotation of the first described swivel mount is negative 180 degree to positive 180 degree.
The anglec of rotation of the second described swivel mount is negative 180 degree to positive 180 degree.
Claims (10)
1. a kind of microscope objective rotation light path it is characterised in that:It includes object lens interface adapter, the first swivel mount, and first
Right optical adjustment frame, the second swivel mount, the first relay lenss, the second right optical adjustment frame, the 3rd right optical adjustment frame,
Second relay lenss, caged cube, the input of object lens interface adapter is connected with outside microscopical microscope adapter, thing
The outfan of mirror interface adapter is connected with the input of the first swivel mount, the outfan of the first swivel mount and the first right optical
The input of adjustment frame connects, and the outfan of the first right optical adjustment frame is connected with the input of the second swivel mount, the second rotation
The outfan of pivoted frame is connected with the input of the first relay lenss, and the outfan of the first relay lenss and the second right optical adjust
The input of frame connects, and the outfan of the second right optical adjustment frame is connected with the input of the 3rd right optical adjustment frame, the
The outfan of three right optical adjustment frames is connected with the input of the second relay lenss, the outfan of the second relay lenss and caged
Cubical input connects;
Described object lens interface adapter be used for by various object lens use external screw thread be converted to standard thread and with microscope phase
Connect;
The first described swivel mount is used for realizing 360 degree of rotations, and rotation mode can be continuous or stepping, and type of drive can be manual
Or be electronic, and there is locking device make it fixing at an arbitrary position;
The first described right optical adjustment frame is used for realizing installing reflecting mirror by 90 degree of Beam rotation, reflecting mirror can according to
Any materials needing, wavelength, the reflecting mirror of shape;
The second described swivel mount is used for realizing 360 degree of rotations, and rotation mode can be continuous or stepping, and type of drive can be manual
Or be electronic, and there is locking device make it fixing at an arbitrary position;
The first described relay lenss are used for for the angle scanning collimated beam of microscope inner sleeve lens being converted to parallel focusing
Light beam, the front focus of the first relay lenss is located at the rear focal point of microscope inner sleeve lens, and the first relay lenss can be root
According to any materials, wavelength, shape, the lens of focal length or the lens combination that need;
The second described right optical adjustment frame is used for realizing installing reflecting mirror by 90 degree of Beam rotation, reflecting mirror can according to
Any materials needing, wavelength, the reflecting mirror of shape;
The 3rd described right optical adjustment frame is used for realizing installing reflecting mirror by 90 degree of Beam rotation, reflecting mirror can according to
Any materials needing, wavelength, the reflecting mirror of shape;
The second described relay lenss are used for for the angle scanning collimated beam of microscope inner sleeve lens being converted to parallel focusing
Light beam, the front focus of the second relay lenss is located at the rear focal point of microscope inner sleeve lens, and the second relay lenss can be root
According to any materials, wavelength, shape, the lens of focal length or the lens combination that need;
Described caged cube is used for accommodating different optical elements, when this utility model is used for NDD detection, caged cube
It is dichroic mirror and optical filter in vivo, the cubical outfan of caged is connected with external objective lens or its adapter, another
Outfan is connected with outside photoelectricity testing part or light-guide device, and the output of outside photoelectric detector is connected with microscope, guide-lighting
Element photoelectricity testing part original with microscope is connected, and when this utility model is not used in NDD detection, caged cube is in vivo
Reflecting mirror, the cubical outfan of caged is connected with external objective lens or its adapter.
2. as claimed in claim 1 a kind of microscope objective rotation light path it is characterised in that:Described the first relay lenss and
Second relay lenss are achromatism structure or apochromatism structure.
3. as claimed in claim 1 a kind of microscope objective rotation light path it is characterised in that:Described the first relay lenss and
The surface of the second relay lenss is coated with high permeability thin film.
4. as claimed in claim 1 a kind of microscope objective rotation light path it is characterised in that:Described the first relay lenss and
The transmission wavelength of the second relay lenss is 100nm to 2um.
5. as claimed in claim 1 a kind of microscope objective rotation light path it is characterised in that:The plated surface of described reflecting mirror
There is high permeability thin film.
6. as claimed in claim 1 a kind of microscope objective rotation light path it is characterised in that:The transmission wave of described reflecting mirror
A length of 100nm to 2um.
7. as claimed in claim 1 a kind of microscope objective rotation light path it is characterised in that:The rotation of the first described swivel mount
Rotating shaft and microscopical imaging optical axis coincidence.
8. as claimed in claim 1 a kind of microscope objective rotation light path it is characterised in that:The rotation of the second described swivel mount
Rotating shaft is through the focus of object lens.
9. as claimed in claim 1 a kind of microscope objective rotation light path it is characterised in that:The rotation of the first described swivel mount
Gyration is negative 180 degree to positive 180 degree.
10. as claimed in claim 1 a kind of microscope objective rotation light path it is characterised in that:The second described swivel mount
The anglec of rotation is negative 180 degree to positive 180 degree.
Priority Applications (1)
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CN201620797502.6U CN205942076U (en) | 2016-07-27 | 2016-07-27 | Rotatory light path of microscope objective |
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CN201620797502.6U CN205942076U (en) | 2016-07-27 | 2016-07-27 | Rotatory light path of microscope objective |
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Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
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CN107450180A (en) * | 2017-10-12 | 2017-12-08 | 凝辉(天津)科技有限责任公司 | A kind of adaptive optics passes picture flexible optical circuit |
CN108614351A (en) * | 2016-12-12 | 2018-10-02 | 凝辉(天津)科技有限责任公司 | A kind of microscope with rotary type object lens |
CN109839732A (en) * | 2019-01-30 | 2019-06-04 | 中国科学技术大学 | A kind of cage construction laser scanning co-focusing micro imaging system and method |
CN110651214A (en) * | 2017-03-21 | 2020-01-03 | 苏州速迈医疗设备有限公司 | Optical adapter for a microscope and method for adjusting the orientation of an optical image |
CN113359287A (en) * | 2021-06-11 | 2021-09-07 | 江苏德恩医学技术有限公司 | Angle-adjustable rotary objective and microscope |
-
2016
- 2016-07-27 CN CN201620797502.6U patent/CN205942076U/en not_active Expired - Fee Related
Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
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CN108614351A (en) * | 2016-12-12 | 2018-10-02 | 凝辉(天津)科技有限责任公司 | A kind of microscope with rotary type object lens |
CN108614351B (en) * | 2016-12-12 | 2020-07-10 | 凝辉(天津)科技有限责任公司 | Microscope with rotatable objective lens |
CN110651214A (en) * | 2017-03-21 | 2020-01-03 | 苏州速迈医疗设备有限公司 | Optical adapter for a microscope and method for adjusting the orientation of an optical image |
CN110651214B (en) * | 2017-03-21 | 2022-04-19 | 苏州速迈医疗设备有限公司 | Optical adapter for a microscope and method for adjusting the orientation of an optical image |
CN107450180A (en) * | 2017-10-12 | 2017-12-08 | 凝辉(天津)科技有限责任公司 | A kind of adaptive optics passes picture flexible optical circuit |
CN109839732A (en) * | 2019-01-30 | 2019-06-04 | 中国科学技术大学 | A kind of cage construction laser scanning co-focusing micro imaging system and method |
CN109839732B (en) * | 2019-01-30 | 2023-10-20 | 中国科学技术大学 | Cage structure laser scanning confocal microscopic imaging system and method |
CN113359287A (en) * | 2021-06-11 | 2021-09-07 | 江苏德恩医学技术有限公司 | Angle-adjustable rotary objective and microscope |
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